Table of Contents

Safety Information 6

Specifications 7

Wiring Diagrams and Schematics 8

Sequence of Operation 9

Pre-Run Sequence 9

Run Sequence 10

Post-Run Sequence 10

Operator Interface 11

Home Screen 12

Operator Access Level – Log In/Out 15

Status 19

System 20

Operation 21

Performance 28

Tornado Plot 33

Tanks 35

Alarms 37

I/O 38

Analog Inputs 1-16 39

Analog Inputs 17-23 41

Digital Inputs 43

Analog Outputs 44

Digital Outputs 45

Communication 46

Variable Frequency Drive 48

Metrics 49

Trends 51

Events 54

Event List 55

Event Details 57

Process 58

Alarms 59

Shutdowns 60

Faults 61

Faults - Variable Frequency Drive 61

Maintenance 62

Configuration/Parameters 64

Operation 65

Main Pump 66

Support Pumps 74

Pressure Control Valve 76

Block Valve 84

General 85

Independent Open Conditions 88

Independent Close Conditions 92

Variable Frequency Drive 96

Motor 100

Pump Curve 101

Custom Coefficients 103

Custom 7-Point 106

Analog Inputs 108

(AI1) Suction Pressure 111

(AI2) Discharge Pressure 112

(AI3) Tank Level 113

(AI4) Well Casing Pressure 115

(AI5) Wellhead Pressure 116

(AI6) Thrst Chmbr Vib 117

(AI7) Discharge Flow 118

(AI8) Auxiliary Flow 120

(AI9) Prsr Ctrl Valve Pos 122

(AI10/16) Thrst Chmbr Oil Temp 123

(AI11) Signal-Following Cmd 125

(AI12) Mtr Brng In Vib 127

(AI13) Mtr Brng Out Vib 129

(AI14) Auxiliary Tank 1 Lvl 131

(AI15) Auxiliary Tank 2 Lvl 133

(AI17) Mtr Winding 1 Temp 135

(AI18) Mtr Winding 2 Temp 136

(AI19) Mtr Winding 3 Temp 137

(AI20) Motor Bearing Front Temperature 138

(AI21) Mtr Brng Rear Temp 139

(AI22) Pump Housing Temp 140

(AI23) Ambient Temp 141

Filter Differential Pressure 142

Digital Inputs 144

(DI1) Hand 146

(DI2) Auto 148

(DI3) User Start 150

(DI4) Tank Level Start 152

(DI5) Tank Level Stop 154

(DI6) TC Oil Pmp Run Cnfrm 156

(DI7) Chrg Pmp Run Cnfrm 158

(DI8) Prsr Ctrl Valve Clsd 160

(DI9) Block Valve Clsd 162

(DI10) Block Valve Open 164

(DI11) TC Oil Rsrvr Lvl Low 166

(DI12) Thrst Chmbr Oil Lvl Low 169

(DI13) Tank Level High 172

(DI14) Field Shutdown 175

(DI15) TC Oil Flow 178

(DI16) Multipurpose 181

Analog Outputs 184

(AO1) Pressure Control Valve Position 185

(AO2) Multipurpose 187

Maintenance Reminders 190

System 194

General 195

SD Card 198

Device Communication 205

SCADA/Modbus Register Map 209

Monitors (16-Bit Holding Registers) - Read-Only (0x03) 209

Monitors (32-Bit Holding Registers) – Read-Only (0x03) 217

Monitors (Bits/Coils) – Read-Only (0x01) 218

Alarm Codes (Register 143) 224

Shutdown Codes (Register 144) 227

Fault Codes (Register 145) 230

VFD Fault Codes (Register 146) 231

Parameters (16-Bit Holding Registers) – Read/Write 237

Parameters (32-Bit Holding Registers) – Read/Write 268

Parameters (Bits/Coils) – Read/Write 270

Parameters (32-Bit Floating Point Holding Registers) – Read/Write 274

Technical Support 275

 

 

Safety Information

! CAUTION !

Always verify that the power has been disconnected from both the panel and the Fuji MEGA variable frequency drive before making changes to the wiring.

 

 

 

High DC voltages may still be present for a period of time after main power has been removed from the variable frequency drive. Take note of the red Charge LED, labeled CRG, located on the drive. Depending on the size of the drive, the LED may be visible through the front cover. The LED will go dark when the DC bus has been discharged. Until then, potentially dangerous voltages may still be present for several minutes after disconnecting power.

Always verify that terminals are no longer powered by using a properly working and tested multimeter.

Specifications

 

 

 

Wiring Diagrams and Schematics

 

Please note that all wiring to and from the controller should be shielded in order to reduce any potential for electrical interference. Using unshielded wiring may result in erratic and unpredictable behavior.

 

 

Sequence of Operation

The OptiPump HPS controller follows a defined sequence of steps during startup, running, and stopping of the system. The steps help to ensure proper and safe operation of the system, and attempt to prevent damage in the event of equipment or device failure. Some steps may be optional depending on features included with the system. Use extreme caution when altering any configuration options that were set during the initial commissioning of the system, as an improperly configured system could result in equipment damage or injury to personnel. Always refer to the most recent revision of the Operation and Configuration Manual and consult qualified technical support or engineering staff if any question regarding physical modification or changes in configuration parameters arises.

 

Pre-Run Sequence

The Pre-Run sequence begins when the HOA switch is in the Hand or Auto position, and the configured start conditions have been met. If the Pre-Run sequence is aborted for any reason (including by the operator or an event), the Pre-Run sequence equipments states are set back to their waiting/idle positions. The Post-Run sequence will not run if the Pre-Run sequence is aborted prior to successful completion.

 

1. If enabled, start the thrust chamber oil pump, wait to confirm the thrust chamber oil pump is running, and then wait for the thrust chamber oil pump pre-run timer to elapse. Set a fault event if the thrust chamber oil pump does not confirm running within 5 seconds.
   
   
2. If the block valve control mode for sequence operation is enabled, command the block valve to open and wait for the block valve to confirm the full-open position. Set a fault event if the block valve does not confirm the full-open position within the travel time.
   
   
3. Command the pressure control valve to the start position.
   
   
4. If the pressure control valve feedback is configured for analog or both feedback, wait for the pressure control valve position to be within ±5% of the commanded position. Set a fault event if the pressure control valve position fails to move to ±5% of the commanded position within the travel time.
   
   
5. If the pressure control valve feedback is configured for digital or both feedback, wait for the pressure control valve to confirm not closed. Set a fault event if the pressure control valve fails to confirm not closed within the travel time.
   
   
6. If enabled, start the charge pump, confirm the charge pump is running, and wait for the charge pump pre-run timer to elapse. Set a fault event if the charge pump does not confirm running within 5 seconds.
   
   
7. Pre-Run sequence complete.
   
   

 

Run Sequence

The Run sequence begins after the Pre-Run sequence successfully completes, and comprises the main control loop for the system. The controller will continually run this process until a stop condition has been met.

 

1. Command the variable frequency drive to run and control the speed based on configured parameter values.
   
   
2. Hold the pressure control valve at the start position, start the stabilization timer, and wait for the stabilization timer to elapse.
   
   
3. Release the pressure control valve from the start position and allow the pump curve to automatically control the commanded position.
   
   
4. Continue running the normal process control until a stop condition has been met.

 

Post-Run Sequence

The Post-Run sequence begins when a stop condition has been met while running. If a shutdown or fault event occurs while running, the Post-Run sequence will be followed. The Post-Run sequence will not run if the Pre-Run sequence is aborted prior to successful completion.

 

1. Wait for the variable frequency drive to decelerate and come to a stop.
   
   
2. If the block valve control mode for sequence operation is enabled, command the block valve to close.
   
   
3. Command the pressure control valve to the fully closed position.
   
   
4. If the thrust chamber oil pump is enabled, start the thrust chamber oil pump post-run timer and wait for the timer to elapse.

 

5. If the charge pump is enabled, start the charge pump post-run timer (simultaneously with the thrust chamber oil pump post-run timer) and wait for the timer to elapse.
   
   
6. Post-Run sequence complete.

 

Operator Interface

The OptiPump HPS controller uses a color touchscreen interface to display information and interact with the local operator. The touchscreen uses a resistive touchscreen, which works well for operators with bare fingers, or when the operator is wearing gloves or using a stylus. To select an option on the screen, the operator need only lightly touch the button or area indicated.

Note:
During periods of operator inactivity, the OptiPump HPS controller may turn off the display, very similar to a blank screensaver on a desktop or laptop computer. If power is available to the controller, simply touch anywhere on the screen to enable/wake the local display. The time for this feature can be adjusted, or disabled, in the System configuration settings.

Configuration and operation of controller is performed primarily via the menu located on the right side of the screen. This menu is context-sensitive – that is, the content will change depending on which screen is currently displayed. The text located just below the Home button near the top of the menu indicates which menu is currently displayed. The Home button located at the top of the menu is present on all menus, regardless of context. This button will always return the operator immediately to the Home screen. The AID logo in the upper left corner of the screen functions as a Home button as well.

Generally, if an item on the screen is blue, the item is touch-sensitive, and will react when pressed. If an item is Gray, the item is touch-sensitive, but currently disabled for some reason. This reason could be that the function is not active or that the operator is not logged-in. An example of the Home and Main Menu is shown below.

 

Button Examples

 

 

Home Screen

 

 

The Home screen provides an overview of the operational values of the HPS system, and is used as the launching point for navigating to more advanced features of the controller, such as configuration and diagnostic information. The Home screen will automatically change the displayed flow diagram based on the options that are enabled. For example, the charge pump and block valve will automatically appear when enabled in the Support Pumps and Block Valve configuration settings.

Operational controls are also available at the bottom of the Home screen. When the Hand-Off-Auto (HOA) switch is in the Hand position, the Hand Control Start and Stop buttons become active – as indicated by their transition from gray to blue. If a fault or shutdown is currently active, the Reset button will become active in order for the operator to manually reset the fault or shutdown.

 

 

HOA Status

 System Status

 

 

Operator Access Level – Log In/Out

Access to the configuration parameters of the system is restricted by a user/password system. Local operators must log-in with the password of the desired access level. When logged-out, the local operator can view all of the configuration parameter values, but cannot change the values. This feature can be useful when on-site personnel need to verify operational parameters without the need to provide the personnel with the ability to change the parameters.

The current access level is shown in the lower right corner of the screen, just below the Log In/Out button.

The OptiPump HPS controller supports several types of operator access levels:

 

Access Level

 

In order to modify configuration parameters, the local operator must first log-in by pressing the Log In/Out button. The Log In/Out button is located at the bottom of the menu located on the right side of the screen, and is available on all menus regardless of context. After the button is pressed, the Log In screen will be displayed, with the option to select between the Limited Operator and Full Supervisor access levels. 

 

Log In

 

After pressing either of the access level buttons, the operator will be prompted for the password for the selected access level.

 

Password Entry

 

Entering the correct password will result in the display returning to the screen from which the Log In/Out button was pressed. Pressing the Esc button will return to the Log In screen, and pressing the Back button from the Log In screen will also result in the display returning to the screen from which the Log In/Out button was initially pressed.

Log Out

 

Once the local operator has completed making changes to the configuration parameters, the operator, as a good practice, should log-out before walking away from the controller. This prevents others from accidentally making changes to the configuration. After pressing the Log In/Out button, the Log Out screen will be displayed, with the option to Confirm Log Out – Yes or No. Pressing the Yes button will result in the operator access level being returned to View-Only and the display returning to the screen from which the Log In/Out button was pressed. Pressing the No button (or the Back button) will result in the display immediately returning to the screen from which the Log In/Out button was pressed, and the operator access level being unchanged.

 

 

Status

The OptiPump HPS controller provides extensive operational status information that can be used as a powerful tool for commissioning, troubleshooting, and optimization of the pump system. This information is available by pressing the Status button on the Main Menu. The status information is available using the View-Only access level, and does not require a password to view.

For convenience, the status information is presented in groups, which are selectable using the menu. If a status group contains subgroups, a selection menu will appear in the content area on the screen.

 

System

 

 

The System status information provides a quick overview of the current operating conditions of the controller, and is presented in two groups:

• Operation
  Status Bits, Process State, and Events

 

• Performance
  Status Bits, Variable Frequency Drive Performance, and Motor Performance

 

Operation

 

 

Command and Status bits are duplicated on both the System Operation and System Performance status screens in order to provide a quick reference for the local operator, without the need to flip back and forth between screens for the needed information.

Command and Status bits are displayed in white text over a black background when in the reset/inactive (logic 0) state.  During normal operation, Command and Status bits are displayed in black text over a green background when in the set/active (logic 1) state, or when in need of immediate attention, in white text over a red background.

 

Command Bits

Status Bits

Process - System

 

 

Process - Pre-Run

Process - Post-Run

Events - Alarm

Events - Shutdown

 

 

Events - Fault

 

 

Performance

 

 

Command and Status bits are duplicated on both the System Operation and System Performance status screens in order to provide a quick reference for the local operator, without the need to flip back and forth between screens for the needed information.

Command and Status bits are displayed in white text over a black background when in the reset/inactive (logic 0) state.  During normal operation, Command and Status bits are displayed in black text over a green background when in the set/active (logic 1) state, or when in need of immediate attention, in white text over a red background.

 

Command Bits

Status Bits

Variable Frequency Drive

Motor

 

Tornado Plot

 

 

The Tornado Plot, aptly named for the funnel-like shape created by the acceptable in-curve operation boundaries, provides a visual representation of where the main pump is currently operating in relation to the defined main pump curve. The x-axis is flow, while the y-axis is discharge pressure. The acceptable in-curve operation area, highlighted in red, moves up and down the tornado diagram automatically, based on the speed of the main pump. The vertical and horizontal red lines create a crosshair that marks the current operating point of the main pump. If the current operating point is outside the red area, the pump is out-of-curve. Operating the main pump out-of-curve reduces efficiency and can damage the equipment. The pressure control valve will automatically attempt to keep the current operating point inside the acceptable in-curve operation area.

The Tornado Plot automatically refreshes once per minute. However, the operator can force the data to be refreshed immediately by pressing the Update Now button in the upper left corner of the screen.

The best efficiency point (BEP) at 60 Hz, based on the defined main pump curve, is displayed in the upper right corner of the plot.

For reference, several monitor values are included at the top of the screen.

Monitors

 

 

Tanks

 

 

The Tanks status screen provides a visual overview of the tank levels. For installations with multiple tanks that require monitoring, the OptiPump HPS controller can be configured to support up to 6 tanks (including the main tank that may be used for start/stop and speed control of the main pump).

Several analog inputs can be configured for tank support. Enabling the tank support parameter on the associated analog input will allow the measured value to be shown as a tank on the Tanks status screen. Each of the 6 available tanks can be associated with one of these analog inputs, so the ordering of the tanks on this screen is determined by the operator. If a tank is not linked to an analog input, that tank will not be visible.

The tanks are numbered 1 through 6, starting in the upper left corner, then moving to the right. Tank 1 is located in the upper left corner. Tank 2 is located in the top row, middle. Tank 3 is located in the upper right corner. Tanks 4 through 6 follow a similar layout for the second row.

The operator defined name of the analog input is shown underneath the associated tank.

 

Analog inputs that can be assigned to tanks:

• (AI3) Tank Level
• (AI11) Signal-Following Cmd
• (AI12) Mtr Brng In Vib
• (AI13) Mtr Brng Out Vib
• (AI14) Auxiliary Tank 1 Lvl
• (AI15) Auxiliary Tank 2 Lvl

Alarms

 

 

Alarm events serve to notify the operator or external equipment of a condition that warrants attention, but does not yet need to stop the process.  Since the system continues to run when alarm events occur, multiple alarms can be present simultaneously.

Individual alarm events are listed on the Alarms screen. Alarm events that are not currently present (inactive/OK) are displayed in black text over a green background. When an alarm event is currently present (active), the individual alarm indicator will be displayed in white text over a red background.

For analog and digital input alarms, the text on the individual alarm indicators will automatically be updated with the names entered by the operator on the configuration screen for the associated input.

Each analog input can be configured for up to four independent alarm setpoints, but only one alarm indicator per analog input is shown on the Alarms screen. The alarm indicator for each of the analog inputs shown will indicate an alarm condition if ANY of the four alarm conditions associated with that analog input is present. For a detailed breakdown of the analog input alarm events, refer to Status > I/O > Analog Inputs 1-16 and Status > I/O > Analog Inputs 17-23.

I/O

 

 

The OptiPump HPS controller provides a robust set of analog and digital I/O that allows for monitoring and control of a variety of external devices. For operator simplicity, the analog and digital I/O status information is grouped by I/O type.

 

Analog Inputs 1-16

 

 

Analog inputs 1 through 16 are shown on the first Analog Inputs I/O status screen. Each row in the table represents a single analog input, and provides the following:

• Name (configurable, however some inputs have a dedicated function)
• Current Measured Value (based on the minimum and maximum scaling configured)
• Units (configurable or fixed, depending on the function)
• Low-Low Alarm/Shutdown Setpoint Value (configurable)
• Low Alarm/Shutdown Setpoint Value (configurable)
• High Alarm/Shutdown Setpoint Value (configurable)
• High-High Alarm/Shutdown Setpoint Value (configurable)

 

While the Status > Alarms screen groups the four individual alarm/shutdown setpoints into a single indicator, the I/O status screen displays each of the setpoints individually, and color codes the setpoints in the same manner as the alarms screen. A setpoint with no alarm event present (inactive/OK) is displayed in black text over a green background. A setpoint with an alarm event present (active) is displayed in white text over a red background.

 

Analog Inputs 17-23

 

 

Analog inputs 17 through 23, including the calculated filter differential pressure, are shown on the second Analog Inputs I/O status screen. Each row in the table represents a single analog input, and provides the following:

• Name (configurable, however some inputs have a dedicated function)
• Current Measured Value (based on the minimum and maximum scaling configured)
• Units (configurable or fixed, depending on the function)
• Low-Low Alarm/Shutdown Setpoint Value (configurable)
• Low Alarm/Shutdown Setpoint Value (configurable)
• High Alarm/Shutdown Setpoint Value (configurable)
• High-High Alarm/Shutdown Setpoint Value (configurable)

 

While the Status > Alarms screen groups the four individual alarm/shutdown setpoints into a single indicator, the I/O status screen displays each of the setpoints individually, and color codes the setpoints in the same manner as the alarms screen. A setpoint with no alarm event present (inactive/OK) is displayed in black text over a green background. A setpoint with an alarm event present (active) is displayed in white text over a red background.

Digital Inputs

 

 

All 16 digital inputs are available on the single Digital Inputs status screen. Each row in the table represents a single digital input, and provides the following:

• Name (configurable, however some inputs have a dedicated function)
• Input Status (Open or Closed)
• Status (Active or Inactive - each digital input can be configured to be active when open or closed)

 

The status of inactive digital inputs is displayed with white text over a black background, while the status of active digital inputs is displayed with black text over a green background.

Some digital inputs can be configured for alarm and shutdown events.  If the status of a digital input is active and an alarm event is present (active) the status will be displayed in white text over a red background.

•  

Analog Outputs

 

 

Each row in the table represents a single analog output, and provides the following information:

• Name (dedicated, not configurable)
• Current Output Value in Scaled Units

 

Analog Output 1 is dedicated to controlling the pressure control valve position. 100% represents commanding the pressure control valve to the fully-open position, regardless of whether the analog output is configured for 4 mA at 100% or 20 mA at 100%.

Analog Output 2 is multipurpose, and configurable by the operator.

 

Digital Outputs

 

 

The Digital Outputs status screen presents information in a similar layout to the Digital Inputs status screen. The key difference is the digital outputs do not have alarm indications, as the outputs cannot be configured for alarm or shutdown events. Each row in the table represents a single digital output, and provides the following information:

• Name (dedicated, not configurable)
• Output Status (Open or Closed)
• Status (Active or Inactive - each digital output can be configured to be active when open or closed)
  
  

The status of inactive digital outputs is displayed with white text over a black background, while the status of the active digital outputs is displayed with black text over a green background.

 

Communication

 

 

The OptiPump HPS controller supports several configurable data communication methods. The Communication Status screen summarizes all of the communication configuration parameter values and key communication statistics on a single status screen. The availability of all the communication data in a single location provides the operator or technician with a quick overview in a single location, without the need for passwords or navigating multiple screens to locate the necessary information.

Ethernet communication between the OptiPump HPS controller and the variable frequency drive is required. Serial communication between the two devices is NOT supported.

Serial communication is available for SCADA communication with the OptiPump HPS controller. However, Ethernet communication is highly recommended for both speed and reliability.

 

 

Stable, reliable Ethernet communication between the OptiPump HPS controller and the variable frequency drive is a critical component to the optimal performance of the system as a whole. Since unknown site conditions may affect the quality of the communications link at the time of installation or later when site conditions change, the Communication Status screen provides capture of communication error messages, if errors occur.

Each step in the communication process between the controller and the variable frequency drive can be noted by the operator using the 3 rows of communication indicators located at the bottom of the screen. The Comm OK indicator will remain green when communication has been established with the variable frequency drive, and will turn red if a communication error occurs. All other communication indicators will appear to blink during normal and successful communication with the variable frequency drive. A green background indicates that the step is currently running. A black background indicates that the step is currently idle.

Please note that the Read indicators will blink much more often than the Write indicators, as the controller only writes values to the variable frequency drive when particular values require updating.

If a communication error does occur, the communication block that experiences the problem will be shown in the Error Block monitor and the type of communication error shown in the Error Type monitor. Once the communication error has been resolved, the values of Error Block and Error Type are moved to the Last Error Block and Last Error Type monitors, to provide some historical information if the communication error occurs only intermittently.

Finally, the Communication Time monitor displays the amount of time in mS for the entire communication loop to complete. Normally, the communication time required is approximately 100 mS. However, some communication loop passes require additional time to update several values within the variable frequency drive, so the time may vary. If, however, the operator notes that the Communication Time frequently spikes to over 1000 mS, the communication link should be investigated for possible errors in the configuration or damage to the physical communication wiring. Typically, when intermittent communication errors are present, the Total Timeouts monitor will be increasing fairly quickly, as the variable frequency drive is intermittently not responding to the requests or commands sent by the controller.

 

Variable Frequency Drive

 

 

The status indicators and monitor values displayed on the Variable Frequency Drive Status screen are the values read directly from the variable frequency drive monitor registers. The values are unmodified or manipulated, and can be used for troubleshooting when checking to verify that the information being presented by the variable frequency drive to the controller for decision-making are expected and/or sensible values.

Metrics

 

 

Run-time and flow data are tracked on the Metrics Overview screen. Metrics data can be used for determining when equipment maintenance should be performed and/or if daily flow performance has been affected by changes to the system.

Run-time monitors are available for the following devices:

• Panel (tracks the powered-on time, and increments even when the pumps are not running)
• Main Pump
• Charge Pump
• Thrust Chamber Oil Pump

 

The OptiPump HPS controller supports two flow meters: one is dedicated for the discharge flow and one for general purpose use. When the Flow Totalizer parameter is enabled for Analog Input 8, the totalized flow monitors will appear on the Metrics Overview screen (shown as the Auxiliary Flow monitors above). The Discharge Flow monitors for Analog Input 7 will always be visible.

The Total Flow Today monitor value is automatically moved to the Total Flow Previous Day monitor everyday at midnight.

Trends

 

 

Live plotting of monitor values can be helpful when looking for trends, commissioning, troubleshooting, or fine-tuning a particular device response or the system overall. The OptiPump HPS controller can simultaneously plot 6 individual monitor values, called curves, on the screen.

The available monitor values that can be plotted are grouped according to the monitor scaling: by whole value, tenth, and hundredth. Plotted monitors are selected by the operator using the 6 Curve buttons at the bottom of the screen. The field immediately above the Curve buttons displays the currently active monitor value and the color of the line that will be plotted on the screen.

Depending on the data that needs to be plotted and the number of curves selected, creating the plot may require a short period of time.

 

 

Pressing a Curve button will display a curve selection screen. The currently selected monitor to be plotted is marked with a Select button with a gray background. The operator can select a different monitor value to be plotted by simply pressing the Select button next to the desired monitor, then pressing the Back button to return to the screen with the plotted data.

For analog input monitors, the analog input name configured by the operator will be shown. The monitor lists below, show the default names for reference.

Curve 1 and 2 (Scale X) Monitor Values:

• None
• Speed
• Voltage
• Current
• Torque
• Horsepower
• (AI1) Suction Pressure
• (AI2) Discharge Pressure
• (AI4) Well Casing Pressure
• (AI5) Wellhead Pressure

Curve 3 and 4 (Scale X.X) Monitor Values:

• None
• (AI3) Tank Level
• (AI7) Discharge Flow
• (AI8) Auxiliary Flow
• (AI9) Prsr Ctrl Valve Pos
• (AI10/16) Thrst Chmbr Oil Temp
• (AI14) Auxiliary Tank 1 Lvl
• (AI15) Auxiliary Tank 2 Lvl
• (AI17) Mtr Winding 1 Temp
• (AI18) Mtr Winding 2 Temp
• (AI19) Mtr Winding 3 Temp
• (AI20) Mtr Brng Frnt Temp
• (AI21) Mtr Brng Rear Temp
• (AI22) Pump Housing Temp
• (AI23) Ambient Temp

 

Curve 5 and 6 (Scale X.XX) Monitor Values:

• None
• (AI6) Thrst Chmbr Vib
• (AI11) Signal-Following Command
• (AI12) Mtr Brng in Vib
• (AI13) Mtr Brng Out Vib

Events

Process events create log entries of important actions that occur during operation. Process conditions that stray outside of normal operation bounds can trigger alarm, shutdown, and fault events. Some event conditions are configurable, and others have fixed limits that cannot be changed or disabled. The OptiPump HPS controller uses four classifications of events, based on severity (listed below from least to most severe):

1. Process
   • Occur during normal operation, so do not alert the operator.
   • Record that the action occurred, in case the operator needs to review the sequence to verify proper operation or investigate the actions that occurred during the lead-up to a problem.

 

2. Alarms

• May occur during normal operation, so warn the operator, but continue the process.
• When alarm event conditions are met, the controller indicates a warning message and records the event. The system continues to operate. If the alarm event conditions are no longer met while the system is running, the alarm event automatically resets/clears. Because alarm events do not stop the system, multiple alarm events may be active at the same time.
  
  

3. Shutdowns

• Should not occur during normal operation, so stop the process.
• When shutdown event conditions are met, the controller immediately stops the process and records the event. If running, the main pump will come to a full stop, and the Post-Run sequence will run. A shutdown event may be configured to automatically restart after a set time has elapsed or may be configured to require the operator to manually reset/clear the shutdown event.
  
  

4. Faults (Controller and Variable Frequency Drive)

• Should never occur during normal operation and likely indicates a hardware failure, so stop the process.
• When fault event conditions are met, the controller immediately stops the process and records the event. If running, the main pump will come to a full stop, and the Post-Run sequence will attempt to run. A fault event cannot be configured to automatically restart, and must be reset/cleared by the operator.
• If a fault event occurs, the operator should thoroughly investigate the cause, and make any necessary repairs before restarting the system.

 

Event List

 

 

The OptiPump HPS controller can store up to 100 events per event type for alarm, shutdown and fault events, and up to 5000 process events. Events are grouped by classification. The classification can be selected from the menu located on the right side of the screen. When an event type is selected from the menu, a list of the events will be displayed, with the most recent event shown at the top. Each page within the event type displays 10 events. The Prev Page and Next Page buttons at the top of the screen move backward and forward in the list, displaying the previous or next 10 events. If known, the operator can jump to a specific page of events using the page number button in the upper left corner of the screen.

Each event shown in the list displays the date and time the event occurred, and a short text description. The Detail buttons located on the left side of the event list switch to the Event Detail screen, which displays a snapshot of the operating conditions at the time the event was set.

 

 

Process events do not record a snapshot at the time the entry is recorded. Since the system is operating normally, the SD card data logging is recommended for tracking performance in this case.

 

Event Details

 

 

Navigation on the Event Details screen operates similarly to the Event List Screen. The Prev Page and Next Page buttons at the top of the screen move backward and forward one event at a time, displaying the snapshot data at the time of the event. If known, the operator can jump to a specific page (event) using the page number button in the upper left corner of the screen.

The snapshot data shown for the event are the same values available on the System Status and I/O Status screens. For more detail on the values, refer to the sections on the System Status and I/O Status screens.

Press the Back button located in the lower left corner of the screen to return back to the Event List screen.

 

Process

 

 

Alarms

 

 

Shutdowns

 

 

Faults

 

Faults - Variable Frequency Drive

 

 

Maintenance

 

 

The OptiPump HPS controller includes a built-in Maintenance Reminder system that can automatically remind operators of the need to perform maintenance and other tasks at set intervals. When one or more of the Maintenance Reminders becomes active, a notification appears on the Home screen, a Modbus SCADA indication bit is set, and a Process event entry is recorded. 

 

The Maintenance Overview screen displays the status of all 10 Maintenance Reminders:

• Status (OK, Attention, or Disabled)
• Time Remaining (hours remaining until the reminder becomes active if configured for run-time)
• Next Reminder (date and time the reminder will become active if configured for monthly)
• Reminder Name (the operator-defined name for the reminder)

 

When a Maintenance Reminder becomes active, the associated Reset button will also become active when the operator is logged-in as the Full Supervisor. Only the Full Supervisor can reset an active Maintenance Reminder. As a good practice, the reminder should not be reset until after the maintenance task has been performed.

When reset, a Maintenance Reminder configured for run-time based notification will reload the Time Remaining monitor with the value set in the associated Run-Time Hours parameter. For a Maintenance Reminder configured for Monthly notification, resetting the reminder will update the Next Reminder monitor with the next available date configured in the associated Day of Month parameter.

 

Configuration/Parameters

The OptiPump HPS controller is highly versatile and configurable to meet a wide range of site requirements. The flexibility built into the controller allows the equipment to be tailored to meet the specific needs of the site without the need for custom program changes. 

All configurable parameters are accessible via the Configure button on the Main Menu of the Home screen. Parameters are protected from modification by a password, which requires the operator to log-in prior to making changes. All parameters are viewable, but cannot be modified, without logging-in. This can be helpful when troubleshooting with personnel on site that may not be authorized to make changes, but can assist in verifying an improperly configured option before sending qualified personnel to the site.

For safety of both the equipment and personnel, only qualified operators should make changes to the configuration parameters.

 

Operation 

Configuration parameters related to the operation of the controller and connected equipment are available in:

Configure > Operation

 

Main Pump

Configuration parameters related to the Main Pump are available in:

Configure > Operation > Main Pump

 

Main Pump - Start/Stop > Start / Stop Source

Start / Stop Source sets the control signal responsible for starting and stopping the main pump.

• Disabled (1/6)

When the Start / Stop Source is set to Disabled, the system will not run. For safety, if the controller battery, which maintains the current configuration parameter values, fails, the Start / Stop Source will default to Disabled to indicate to the operator that other equipment settings have been lost and corrective action will need to be taken before restarting the system.

 

• Analog Suction Pressure (AI1) (2/6)

The analog signal connected to (AI1) Suction Pressure will control the starting and stopping of the main pump. Start Setpoint and Stop Setpoint will be enabled.

 

• Analog Discharge Pressure (AI2) (3/6)

The analog signal connected to (AI2) Discharge Pressure will control the starting and stopping of the main pump. Start Setpoint and Stop Setpoint will be enabled.

 

• Analog Tank Level (AI3) (4/6)

The analog signal connected to (AI3) Tank Level will control the starting and stopping of the main pump. Start Setpoint and Stop Setpoint will be enabled.

 

• Maintained Contact Tank Level (DI4) (5/6)

The dry contact connected to (DI4) Tank Level Start will control the starting and stopping of the main pump. The contact must be maintained in the active state in order for the system to run. If the contact becomes inactive, the system will stop. Start Setpoint and Stop Setpoint will be disabled. This option can also be used when an external control system is used to command the OptiPump HPS controller to start and stop.

 

• Momentary Contact Tank Level (DI4/DI5) (6/6)

The dry contact connected to (DI4) Tank Level Start will control the starting of the main pump. The contact does NOT need to be maintained in order for the system to continue to run. The dry contact connected to (DI5) Tank Level Stop will control the stopping of the main pump. The contact does NOT need to be maintained in order for the system to stop. Start Setpoint and Stop Setpoint will be disabled. This option can be used in tank configurations that use two float switches, rather than an analog pressure transducer.

 

Main Pump - Start/Stop > Start Setpoint

When the Start / Stop Source is configured to use an analog input for control, the value of the analog input must meet the Start Setpoint value in order to start the main pump. If the Start Setpoint is greater than the Stop Setpoint, the system will not start until the analog input value is greater than or equal to the Start Setpoint. If the Start Setpoint is less than the Stop Setpoint, the system will not start until the analog input value is less than or equal to the Start Setpoint.

The Start Setpoint units will automatically change based on the analog input selected in Start / Stop Source.

If the Start / Stop Source is not configured to use an analog input, the Start Setpoint will be disabled.

 

Main Pump - Start/Stop > Stop Setpoint

When the Start / Stop Source is configured to use an analog input for control, the value of the analog input must meet the Stop Setpoint value in order to stop the main pump. If the Start Setpoint is greater than the Stop Setpoint, the system will not stop until the analog input value is less than or equal to the Stop Setpoint. If the Start Setpoint is less than the Stop Setpoint, the system will not stop until the analog input value is greater than or equal to the Stop Setpoint.

The Stop Setpoint units will automatically change based on the analog input selected in Start / Stop Source.

If the Start / Stop Source is not configured to use an analog input, the Stop Setpoint will be disabled.

 

Main Pump - Start/Stop > User Start

Digital input (DI3) User Start acts as a remote "run enable" permissive input.

• Disabled (1/2)

The system will start and stop based on the conditions set by the Start / Stop Source and associated setpoints.

 

• Enabled (2/2)

The system will ignore the Start / Stop Source and associated setpoints until (DI3) User Start is active. If (DI3) User Start becomes inactive, the system will stop immediately without meeting the stop conditions set by the Start / Stop Source.

 

Main Pump - Speed > Speed Source

Speed Source sets the control signal responsible for controlling the speed of the main pump. When using one of the maintain selections, refer to the Main Pump - Speed - Advanced configuration parameters for additional information.

• Maintain Suction Pressure (AI1) (1/5)

The speed of the main pump will automatically change based on the feedback provided by (AI1) Suction Pressure using a PID loop to maintain the value set in Maintain Setpoint. Maintain Setpoint will be enabled. Fixed Speed will be disabled.

 

• Maintain Discharge Pressure (AI2) (2/5)

The speed of the main pump will automatically change based on the feedback provided by (AI2) Discharge Pressure using a PID loop to maintain the value set in Maintain Setpoint. Maintain Setpoint will be enabled. Fixed Speed will be disabled.

 

• Maintain Tank Level (AI3) (3/5)

The speed of the main pump will automatically change based on the feedback provided by (AI3) Tank Level using a PID loop to maintain the value set in Maintain Setpoint. Maintain Setpoint will be enabled. Fixed Speed will be disabled.

 

• Signal-Following Command (AI11) (4/5)

The speed of the main pump will vary proportionally with the analog signal connected to (AI11) Signal-Following Command. The minimum speed will occur at 4 mA, and the maximum speed will occur at 20 mA. Maintain Setpoint will be disabled. Fixed Speed will be disabled.

 

 

• Operator Manual Entry/Fixed Speed (5/5)

The speed of the main pump will remain fixed at the value entered. Maintain Setpoint will be disabled.

This option can also be used when setting the speed via SCADA is desired.

 

Main Pump - Speed > Maintain Setpoint

When the Speed Source is configured to use one of the maintain analog input selections, the Maintain Setpoint value will be the value that the system attempts to maintain.

The Maintain Setpoint units will automatically change based on the analog input selected in Speed Source.

If the Speed Source is not configured to use a maintain analog input, Maintain Setpoint will be disabled.

 

Main Pump - Speed > Fixed Speed

When the Speed Source is set to Operator Manual Entry/Fixed Speed, the main pump will run at a speed set by Fixed Speed in Hz. The speed of the main pump will not change automatically. 

If the Speed Source is not set to Operator Manual Entry/Fixed Speed, Fixed Speed will be disabled.

 

Main Pump – Speed – PID Monitors

Main Pump - Speed - PID > (AIx) P Band

When the Speed Source is configured to use an analog input to maintain a process value (PV), the (AIx) P Band will set the proportional band around the setpoint in which the PID loop is active. If (AIx) P Band is set to more than 100.0%, the PID function is applied over the entire range.

Running the PID Auto-Tune function is recommended to automatically set this value.

 

Main Pump - Speed - PID > (AIx) I Time

When the Speed Source is configured to use an analog input to maintain a process value (PV), the (AIx) I Time will set the amount of time, as calculated by the PID loop, required to bring the process value to the Maintain Setpoint. If the (AIx) I Time is set too low, the PID loop will react too quickly, resulting in an overshoot of the Maintain Setpoint. If the (AIx) I Time is set too high, the PID loop will react too slowly.

Running the PID Auto-Tune function is recommended to automatically set this value.

 

Main Pump - Speed - PID > (AIx) D Time

When the Speed Source is configured to use an analog input to maintain a process value (PV), the (AIx) D Time will change the response of the PID loop to the rate of change in the error between the process value and Maintain Setpoint. (AIx) D Time can be difficult to adjust by hand in order to provide satisfactory results.

Running the PID Auto-Tune function is recommended to automatically set this value.

 

Main Pump - Speed - PID > Start Auto-Tune

When the Speed Source is configured to use an analog input to maintain a process value (PV), the Start Auto-Tune function will automatically control the speed of the main pump, causing the process value to cycle above and below the Maintain Setpoint. The cycling process allows the controller to calculate the required P Band, I Time, and D Time needed for optimal control of the application. The time required to complete the auto-tune may take several minutes.

Auto-Tune Steps (*must be logged-in as the Full Supervisor to complete these steps):

1. With the desired Speed Source selected and Maintain Setpoint set, start the system in the Auto mode.
2. Wait for the Pre-Run process to complete, and for the main pump to start.
3. Press the Start Auto-Tune button.
4. Wait for the PID loop to gather data on the process. The main pump will automatically speed up and slow down several times, going above and below the Maintain Setpoint value. The Start Auto-Tune button will be disabled during this process.
5. When the auto-tune process has completed, the values for P Band, I Time, and D Time will be automatically updated on the screen, and the Start Auto-Tune button will be enabled again.
6. No further adjustments are typically needed. However, the auto-tune process values can be adjusted by hand to fine-tune the response if the operator believes that the response can be further improved.

 

Main Pump - Speed - Advanced > OptiMode

OptiMode is designed for tank applications, and can be highly effective at lowering the electrical energy required to operate the system. The energy savings reduces the overall cost per barrel of fluid moved and extends the life of components such as bearings, by running the main pump at the minimum speed at start.

Note:
The OptiMode configuration parameter only alters the locations of the setpoints on the Home screen. The operator is still required to choose a Maintain Setpoint value ABOVE the Start Setpoint value when Eco Mode is set to Enabled.

• Disabled (1/2)

A standard tank application places the Start Setpoint near the top of the tank, the Stop Setpoint near the bottom of the tank, and the Maintain Setpoint somewhere in between. In this configuration, the main pump often runs a maximum speed at start, then slows down as it reaches the Maintain Setpoint, and continues to run at minimum speed until reaching the Stop Setpoint. Operating in this manner can be inefficient due to running the main pump at faster speeds for shorter periods of time. Refer to the affinity law requirements for horsepower for more information.

 

 

• Enabled (2/2)

OptiMode lowers the Start Setpoint to between the Stop Setpoint and the Maintain Setpoint. In this configuration, the main pump starts at the minimum speed. If the minimum speed is still fast enough to keep up with the incoming fluid, the main pump will continue to run at the minimum speed until the Stop Setpoint is reached. However, if the minimum speed cannot keep up with the incoming fluid and the tank level continues to rise, the PID loop will automatically increase the speed of the main pump once the tank level reaches the Maintain Setpoint.

 

 

Main Pump - Speed - Advanced > Speed Mismatch Reaction

Reaction to the condition when the Output Frequency exceeds the Command Reference Frequency by ±0.5 Hz for a period equal to the Acceleration Time plus 5 seconds.

During normal operation, the Output Frequency should match the Command Reference Frequency. However, several conditions may cause the two frequencies to mismatch. For example:

1. Current limit is active.
2. Torque limit is active.
3. Overvoltage suppression is active due to an overhauling load.

The controller can be configured to ignore these conditions or alert the operator if these conditions occur.

• Disabled (1/3)

A speed mismatch will be ignored.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

 

Support Pumps

Configuration parameters related to the Support Pumps are available in:

Configure > Operation > Support Pumps

 

Support Pumps - Charge Pump > Charge Pump

The charge pump is a support pump connected to the suction side of the main pump, and is designed to boost the initial pressure to at least a minimum intake pressure level required by the main pump. Depending on the site design, a charge pump may or may not be required for the safe operation of the main pump.

• Disabled (1/2)

A charge pump is not available, and will be skipped during the Pre-Run sequence.

 

• Enabled (2/2)

A charge pump is installed, will be started during the Pre-Run sequence, and continue to run while the main pump is running. If the charge pump fails to confirm a running state during the Pre-Run sequence or during running of the main pump, a failed-to-run fault will be set.

 

Support Pumps - Charge Pump > Pre-Run Time

When Charge Pump is set to Enabled, the Pre-Run Time sets the amount of time that the charge pump will run during the Pre-Run sequence, prior to the main pump starting. The charge pump continues to run after the main pump is started.

The Pre-Run Time is disabled when Charge Pump is set to Disabled.

 

Support Pumps - Charge Pump > Post-Run Time

When Charge Pump is set to Enabled, the Post-Run Time sets the amount of time that the charge pump will run during the Post-Run sequence, after the main pump stops.

 

Support Pumps - Thrust Chamber Oil Pump > Thrust Chamber Oil Pump

The thrust chamber oil pump is a critical support pump responsible for circulating oil through a thrust chamber that is oil cooled. The thrust chamber oil pump continues to run during the Post-Run sequence, after the main pump stops, in order to remove additional heat from the thrust chamber.

• Disabled (1/2)

A thrust chamber oil pump is not used or available, will be skipped during the Pre-Run sequence, and not run while the main pump is running. Running the system with the thrust chamber oil pump disabled should only be used when troubleshooting and for very brief periods of time (seconds only). Major main pump and thrust chamber damage will occur if the system is run for more than a few seconds with the thrust chamber oil pump disabled.

 

• Enabled (2/2)

A thrust chamber oil pump is installed, will start during the Pre-Run sequence, run while the main pump is running, and continue to run during the Post-Run sequence. If the thrust chamber oil pump fails to confirm a running state during the Pre-Run sequence or during the running of the main pump, a failed-to-run fault will be set.

 

Support Pumps - Thrust Chamber Oil Pump > Pre-Run Time

When Thrust Chamber Oil Pump is set to Enabled, the Pre-Run Time sets the amount of time that the thrust chamber oil pump will run during the Pre-Run sequence, prior to the main pump starting. The thrust chamber oil pump continues to run after the main pump is started.

 

Support Pumps - Thrust Chamber Oil Pumps > Post-Run Time

When Thrust Chamber Oil Pump is set to Enabled, the Post-Run Time sets the amount of time that the thrust chamber oil pump will run during the Post-Run sequence, after the main pump stops.

Pressure Control Valve

Configuration parameters related to the Pressure Control Valve are available in:

Configure > Operation > Pressure Control Valve

 

Pressure Control Valve > Control Mode

A pressure control valve, installed on the discharge side of the main pump, is a required and critical component of the system. The pressure control valve is responsible for keeping the main pump in curve - a function that optimizes the efficiency of the system and, more importantly, prevents damage to the main pump and thrust chamber.

The pressure control valve position is set by the controller, using either a manual discharge pressure setpoint entered in Pressure Setpoint or an automatic discharge pressure setpoint that is determined by the controller based on the defined main pump curve. Refer to Configure > Pump Curve for more information.

• Auto Pump Curve

The pressure control valve position will automatically change based on the feedback provided by (AI2) Discharge Pressure using a PID loop to maintain the discharge pressure determined by the controller using the defined main pump curve.

 

• Manual Pressure

The pressure control valve position will automatically change based on the feedback provided by (AI2) Discharge Pressure using a PID loop to maintain the pressure set in Manual Setpoint. Because the main pump curve is not used to control the pressure control valve position, this mode is only recommended for short periods of time during troubleshooting or commissioning.

 

• Manual Position

The pressure control valve will move immediately to the position set in Position Setpoint. The pressure control valve will move to this position even when the system is stopped or the HOA is turned to the Off position. Manually positioning the pressure control valve is intended for use during the installation and commissioning process in order to calibrate the valve position.

 

Valves - Pressure Control Valve > Pressure Setpoint

When Control Mode is set to Manual Pressure, the pressure control valve position will automatically change based on the feedback provided by (AI2) Discharge Pressure using a PID loop to maintain the discharge pressure entered. 

 

Valves - Pressure Control Valve > Position Setpoint

When Control Mode is set to Manual Position, the pressure control valve will immediately move to the position entered. The pressure control valve will move to this position even when the system is stopped or the HOA is turned to the Off position. 

 

Valves - Pressure Control Valve > Travel Time

The Travel Time sets the amount of time required for the pressure control valve to move from the fully closed to the fully open position. If the pressure control valve fails to move to the commanded position within the allotted time, a fault will be set. The specific fault that will be set varies based on the process.

The pressure control valve Travel Time is used for the following:

• Initial Position

During the Pre-Run sequence, the pressure control valve is commanded to move to the position set in Start Position. If Position Feedback is not set to Disabled, and the pressure control valve fails to confirm before the Travel Time elapses, a pressure control valve failed-to-position fault will be set.

If, when Position Feedback is set to Analog (AI9) or Both (AI9/DI8), the position feedback is equal to or exceeds ±5.0% around the commanded position, a pressure control valve failed-to-position fault will be set. For example, if the commanded position is 74%, a pressure control valve failed-to-position fault will be set if the position feedback is less than or equal to 69% or greater than or equal to 79%.

 

• Main Pump Out-of-Curve Detection

After the Pre-Run sequence has successfully completed and the Stabilization Time has elapsed, the Travel Time is also used as a detection time for the main pump out-of-curve detection. If, while the main pump is running, the current operating point falls outside of the defined in-curve area for the time set in Travel Time, a main pump out-of-curve condition will be detected. The reaction to a main pump out-of-curve condition is set by Out of Curve Reaction.

 

• Pressure Control Valve Failed to Control Pressure

After the Pre-Run sequence has successfully completed and the Stabilization Time has elapsed, the Travel Time is also used as a detection time for the detection of the pressure control valve failing to control the target discharge pressure. If, while the main pump is running, the (AI2) Discharge Pressure is equal to or exceeds ±10 PSI of the target discharge pressure for the time set in Travel Time, a pressure control valve failed-to-control pressure condition will be detected. The reaction to a pressure control valve failed-to-control condition is set by Fail to Control Pressure Reaction.

 

• Running Position

After the Pre-Run sequence has successfully completed and the main pump is running, the Travel Time is also used as a detection time for the pressure control valve failing to move to the commanded position. If Position Feedback is not set to Disabled, and the pressure control valve fails to confirm before the Travel Time elapses, a pressure control valve failed-to-position fault will be set. If the pressure control valve successfully confirms the commanded position before the Travel Time elapses, the timer is reset and normal operation continues.

If, when Position Feedback is set to Analog (AI9) or Both (AI9/DI8), the position feedback is equal to or exceeds ±5.0% around the commanded position and the Travel Time elapses, a pressure control valve failed-to-position fault will be set. For example, if the commanded position is 74%, a pressure control valve failed-to-position fault will be set if the position feedback is less than or equal to 69% or greater than or equal to 79% for the amount of time set in Travel Time.

 

Pressure Control Valve – PID Monitors

Pressure Control Valve - PID > Auto P Band

The Auto P Band sets the proportional band around the discharge pressure setpoint in which the PID loop is active. If Auto P Band is set to more than 100.0%, the PID function is applied over the entire range.

Running the PID Auto-Tune function is recommended to automatically set this value.

 

Pressure Control Valve - PID > Auto I Time

The Auto I Time sets the amount of time, as calculated by the PID loop, required to bring the (AI3) Discharge Pressure to the target discharge pressure. If Auto I Time is set too low, the PID loop will react too quickly, resulting in an overshoot of the target discharge pressure. If the Auto I Time is set too high, the PID loop will react too slowly.

Running the PID Auto-Tune function is recommended to automatically set this value.

 

Pressure Control Valve - PID > Auto D Time

The Auto D Time changes the response of the PID loop to the rate of change in the error between (AI3) Discharge Pressure and the target discharge pressure. Auto D Time can be difficult to adjust by hand in order to provide satisfactory results.

Running the PID Auto-Tune function is recommended to automatically set this value.

 

Pressure Control Valve - PID > Start Auto-Tune

The Start Auto-Tune function will automatically control the position of the pressure control valve, causing the discharge pressure to cycle above and below the target discharge pressure. The main pump will move in and out of curve during this process. The cycling process allows the controller to calculate the required P Band, I Time, and D Time needed for optimal control of the pressure control valve. The time required to complete the auto-tune may take several minutes.

In order to reduce the number of variables in the process, Manual Pressure is the recommended setting for Control Method. Running the main pump at a fixed speed can also improve the results of the auto-tune.

Auto-Tune Steps (*must be logged-in as the Full Supervisor to complete these steps):

1. Set Main Pump - Speed > Speed Source to Operator Manual Entry/Fixed Speed and Main Pump - Speed > Fixed Speed to an acceptable value for the main pump.
2.  Set Control Mode to Manual Pressure and Pressure Setpoint to an acceptable target discharge pressure at the speed chosen in Step 1, then start the system in the Auto mode.
3. Wait for the Pre-Run process to complete, the main pump to start, and the Stabilization Time to elapse.
4. Press the Start Auto-Tune button.
5. Wait for the PID loop to gather data on the process. The pressure control valve will automatically change position, resulting in the (AI3) Discharge Pressure value increasing and decreasing around the discharge pressure set in Manual Pressure. The Start Auto-Tune button will be disabled during this process.
6. When the auto-tune process has completed, the values for P Band, I Time, and D Time will be automatically updated on the screen, and the Start Auto-Tune button will be enabled again.
7. Stop the system.
8. No further adjustments are typically needed. However, the auto-tune process values can be adjusted by hand to fine-tune the response if the operator believes that the response can be further improved.
9. Once a successful auto-tune has completed and the pressure control valve reaction accurately maintains the target discharge pressure, return Main Pump - Speed > Speed Source and Control Method to the values necessary for operation of the system.

 

Pressure Control Valve - Advanced > Start Position

During the Pre-Run sequence, the pressure control valve will be commanded from the fully closed position to the Start Position. The starting position of the pressure control valve should be chosen to allow the main pump to be relatively close to the expected in-curve discharge pressure at the expected speed.

 

Pressure Control Valve - Advanced > Stabilization Time

The stabilization time provides a short delay after the main pump starts to allow the main pump to come up to speed and pressurize the wellhead/pipeline before enabling the automatic control of the pressure control valve.

After the Pre-Run sequence has successfully completed and the main pump is running, the pressure control valve Start Position will be held for the value set in Stabilization Time. 

 

Pressure Control Valve - Advanced > Out of Curve Reaction

After the Pre-Run sequence has successfully completed, the main pump is running, and the Stabilization Time has elapsed, the controller enables out-of-curve detection for the main pump. If the main pump is determined to be out of the acceptable curve area for the time set in Travel Time, a main pump out-of-curve condition will be detected.

The controller can be configured to react to an out-of-curve condition in several ways:

• Disabled (1/3)

A main pump out-of-curve condition will be ignored.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Pressure Control Valve - Advanced > Fail to Control Pressure Reaction

After the Pre-Run sequence has successfully completed, the main pump is running, and the Stabilization Time has elapsed, the controller enables the pressure control valve failed-to-control pressure detection. Reaction to the condition will occur when the discharge pressure exceeds the target discharge pressure by ±10 PSI for a period equal to the Travel Time.

The controller can be configured to react to a failed-to-control pressure condition in several ways:

• Disabled (1/3)

A failed-to-control pressure condition will be ignored.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Pressure Control Valve - Advanced > Position Feedback

For the best operational results and system performance, the feedback for the position of the pressure control valve should be implemented using an analog input, (AI9) Pressure Control Valve Position. However, the OptiPump HPS controller supports a number of different feedback options to allow for variability of the field equipment.

• Disabled (1/4)

The pressure control valve does not provide feedback to the controller. The fail-to-control pressure condition and fail-to-position fault related to the pressure control valve are disabled. The pressure control valve will still be commanded to desired positions, but without feedback, the controller can only assume the pressure control valve has moved.

 

• Analog (AI9) (2/4)

The pressure control valve position uses an analog input connected to (AI9) Pressure Control Valve Position to indicate 0-100% open.

 

• Digital (DI8) (3/4)

The pressure control valve position is indicated using a digital input by connecting a dry contact to (DI8) Pressure Control Valve Closed. (DI8) Pressure Control Valve Closed is active when the pressure control valve is fully closed and inactive when the pressure control valve is at some other position other than fully closed.

 

• Both (AI9/DI8) (4/4)

The pressure control valve position is indicated using both an analog input connected to (AI9) Pressure Control Valve Position and a digital input connected to (DI8) Pressure Control Valve Closed.

 

Block Valve

Configuration parameters related to the Block Valve are available in:

Configure > Operation > Block Valve

 

An optional block valve (also referred to as a slam valve), designed to isolate the inlet to the facility when the tanks are full or the wellhead/pipeline from the system when the main pump is stopped, may be installed ahead of the facility or on the discharge side of the main pump, depending on the site requirements. The OptiPump HPS controller enables the block valve to be configured in the field by the operator using a highly customizable control system, all without the need for site-customized firmware to be written.

A Process event will be recorded any time the block valve is commanded to open or close.

 

General

General configuration parameters related to the Block Valve are available in:

Configure > Operation > Block Valve > General 

 

Block Valve - General > Control Mode

The block valve operation is highly configurable by the operator. Please note that the block valve is NOT the pressure control valve, and is NOT designed to keep the main pump in-curve.

• Disabled (1/3)

An optional block valve is not available, and will not be used during operation of the system.

 

• Run Sequence (2/3)

An optional block valve is installed, will be commanded to fully open during the Pre-Run sequence, remain open while the main pump is running, and will be commanded to fully close during the Post-Run sequence. The Run Sequence mode is intended for use when the block valve is installed on the discharge side of the main pump.

 

• Independent (3/3)

An optional block valve is installed, and will operate fully independent of the main pump system. The block valve will open and close based on conditions configured by the operator. The block valve will operate regardless of whether or not the main pump is stopped or running.

 

When operating in the Independent mode, if both open and close conditions are simultaneously met, the closing of the block valve takes priority.

 

Block Valve - General > Travel Time

When the Control Mode is set to Run Sequence or Independent, the Travel Time sets the amount of time required for the block valve to move from the fully closed to fully open and fully open to fully closed position. If the block valve fails to confirm a commanded position after the Travel Time elapses, a block valve failed-to-open fault will be set. Adding 5 to 10 seconds to the required travel time can help to prevent nuisance failed-to-open faults when the travel time of the block valve is inconsistent.

 

Block Valve - General - Independent > Operate When HOA

When the Control Mode is set to Independent, the block valve can be configured to operate depending on the position of the HOA switch.

• Hand/Auto (1/2)

The block valve will operate if the open and close conditions are met when the HOA switch is in the Hand or Auto position. If the HOA switch is in the Off position, the block valve will be commanded to the closed position.

 

• Hand/Off/Auto (2/2)

The block valve will operate if the open and close conditions are met, regardless of the position of the HOA switch.

Operate When HOA is disabled when Control Mode is set to Disabled or Run Sequence.

 

Block Valve - General - Independent > Operate During Sd/Flt

When the Control Mode is set to Independent, the block valve operation can also be configured to operate even when a shutdown or fault is currently active. This allows the block valve to continue to attempt to operate regardless of the state of the system.

• Disabled (1/2)

The block valve will move to the closed position if ANY shutdown or fault is active.

• Enabled (2/2)

The block valve will attempt to continue to operate based on the open and close conditions, even when a shutdown or fault event is currently active. This includes if the block valve fails to open and close.

Operate During Sd/Flt is disabled when Control Mode is set to Disabled or Run Sequence.

 

Independent Open Conditions

Configuration parameters related to the Independent Open Conditions of the Block Valve are available in:

Configure > Operation > Block Valve > Independent Open Conditions 

 

Block Valve – Independent Open Conditions > Open Conditions

The block valve can be commanded to open based on up to four conditions configured by the operator. The command to open the block valve can be required to meet any or all of the four conditions configured.

If an Open Source is set to None, that source is NOT included in the decision making process.

• All Met (1/2)

The block valve will be commanded to open only when ALL four of the open source conditions are met.

 

• Any Met (2/2)

The block valve will be commanded to open if ANY one of the four open source conditions is met.

Block Valve – Independent Open Conditions > Opened Reaction

In cases were an alert or notification is needed any time the block valve is open, the Open Reaction can be configured to set an alarm.

• Disabled (1/2)

No alarm will be set when the block valve is confirmed in the open position.

 

• Alarm (2/2)

A block valve open alarm will be set when the block valve is confirmed in the open position. This alarm will automatically clear when the block valve is no longer confirmed in the open position.

 

Block Valve – Independent Open Conditions > Open Source 1

Block Valve – Independent Open Conditions > Open Source 2

Block Valve – Independent Open Conditions > Open Source 3

Block Valve – Independent Open Conditions > Open Source 4

The analog or digital input used to determine if the block valve should be commanded to open. If an analog input is selected as an Open Source, the When To Open and Open Setpoint will also need to be configured. If a digital input is selected as an Open Source, the condition will be met any time the digital input is active.

• None (1/15)

The Open Source condition will NOT be used to determine if the block valve should be commanded to open.

 

• Analog Input 1 (2/15)

(AI1) Suction Pressure will be used to determine if the block valve should be commanded to open.

 

• Analog Input 2 (3/15)

(AI2) Discharge Pressure will be used to determine if the block valve should be commanded to open.

 

• Analog Input 3 (4/15)

(AI3) Tank Level will be used to determine if the block valve should be commanded to open.

 

• Analog Input 4 (5/15)

(AI4) Well Casing Pressure will be used to determine if the block valve should be commanded to open.

 

• Analog Input 5 (6/15)

(AI5) Wellhead Pressure will be used to determine if the block valve should be commanded to open.

 

• Analog Input 11 (7/15)

(AI11) Signal-Following Cmd will be used to determine if the block valve should be commanded to open.

 

• Analog Input 12 (8/15)

(AI12) Mtr Brng In Vib will be used to determine if the block valve should be commanded to open.

 

• Analog Input 13 (9/15)

(AI13) Mtr Brng Out Vib will be used to determine if the block valve should be commanded to open.

 

• Analog Input 14 (10/15)

(AI14) Auxiliary Tank 1 Lvl will be used to determine if the block valve should be commanded to open.

 

• Analog Input 15 (11/15)

(AI15) Auxiliary Tank 2 Lvl will be used to determine if the block valve should be commanded to open.

 

• Digital Input 13 (12/15)

(DI13) Tank Level High will be used to determine if the block valve should be commanded to open.

 

• Digital Input 14 (13/15)

(DI14) Field Shutdown will be used to determine if the block valve should be commanded to open.

 

• Digital Input 15 (14/15)

(DI15) Thrust Chamber Oil Flow will be used to determine if the block valve should be commanded to open.

 

• Digital Input 16 (15/15)

(DI16) Multipurpose will be used to determine if the block valve should be commanded to open.

 

Block Valve – Independent Open Conditions > When To Open 1

Block Valve – Independent Open Conditions > When To Open 2

Block Valve – Independent Open Conditions > When To Open 3

Block Valve – Independent Open Conditions > When To Open 4

When an analog input has been selected as an Open Source, the When To Open value also needs to be configured. When To Open determines if the Open Source condition is met when the measured value is equal to or GREATER than the setpoint or when the measured value is equal to or LESS than the setpoint.

• Equal or Greater (1/2)

The condition will be met if the measured value of the analog input is equal to or greater than the value of the associated setpoint.

 

• Equal or Less (2/2)

The condition will be met if the measured value of the analog input is equal to or less than the value of the associated setpoint.

When To Open is disabled when the associated Open Source is set to None or a digital input.

Block Valve – Independent Open Conditions > Open Setpoint 1

Block Valve – Independent Open Conditions > Open Setpoint 2

Block Valve – Independent Open Conditions > Open Setpoint 3

Block Valve – Independent Open Conditions > Open Setpoint 4

When an analog input has been selected as an Open Source, the Open Setpoint value also needs to be configured. The Open Setpoint is the scaled value of the analog input that must be met in order for the Open Source condition to be met. The Open Source condition can also be met if the scaled value of the analog input is greater than or less than the value of Open Setpoint, depending on how the associated When To Open parameter is configured.

Open Setpoint is disabled when the associated Open Source is set to None or a digital input.

 

 

Independent Close Conditions

Configuration parameters related to the Independent Close Conditions of the Block Valve are available in:

Configure > Operation > Block Valve > Independent Close Conditions 

 

Block Valve – Independent Close Conditions > Close Conditions

The block valve can be commanded to close based on up to four conditions configured by the operator. The command to close the block valve can be required to meet any or all of the four conditions configured.

If a Close Source is set to None, that source is NOT included in the decision making process.

• All Met (1/2)

The block valve will be commanded to close only when ALL four of the close source conditions are met.

 

• Any Met (2/2)

The block valve will be commanded to close if ANY one of the four close source conditions is met.

Block Valve – Independent Close Conditions > Closed Reaction

In cases were an alert or notification is needed any time the block valve is closed, the Closed Reaction can be configured to set an alarm.

• Disabled (1/2)

No alarm will be set when the block valve is confirmed in the closed position.

 

• Alarm (2/2)

A block valve closed alarm will be set when the block valve is confirmed in the closed position. This alarm will automatically clear when the block valve is no longer confirmed in the closed position.

 

Block Valve – Independent Close Conditions > Close Source 1

Block Valve – Independent Close Conditions > Close Source 2

Block Valve – Independent Close Conditions > Close Source 3

Block Valve – Independent Close Conditions > Close Source 4

The analog or digital input used to determine if the block valve should be commanded to close. If an analog input is selected as a Close Source, the When To Close and Close Setpoint will also need to be configured. If a digital input is selected as a Close Source, the condition will be met any time the digital input is active.

• None (1/15)

The Close Source condition will NOT be used to determine if the block valve should be commanded to close.

 

• Analog Input 1 (2/15)

(AI1) Suction Pressure will be used to determine if the block valve should be commanded to close.

 

• Analog Input 2 (3/15)

(AI2) Discharge Pressure will be used to determine if the block valve should be commanded to close.

 

• Analog Input 3 (4/15)

(AI3) Tank Level will be used to determine if the block valve should be commanded to close.

 

• Analog Input 4 (5/15)

(AI4) Well Casing Pressure will be used to determine if the block valve should be commanded to close.

 

• Analog Input 5 (6/15)

(AI5) Wellhead Pressure will be used to determine if the block valve should be commanded to close.

 

• Analog Input 11 (7/15)

(AI11) Signal-Following Cmd will be used to determine if the block valve should be commanded to close.

 

• Analog Input 12 (8/15)

(AI12) Mtr Brng In Vib will be used to determine if the block valve should be commanded to close.

 

• Analog Input 13 (9/15)

(AI13) Mtr Brng Out Vib will be used to determine if the block valve should be commanded to close.

 

• Analog Input 14 (10/15)

(AI14) Auxiliary Tank 1 Lvl will be used to determine if the block valve should be commanded to close.

 

• Analog Input 15 (11/15)

(AI15) Auxiliary Tank 2 Lvl will be used to determine if the block valve should be commanded to close.

 

• Digital Input 13 (12/15)

(DI13) Tank Level High will be used to determine if the block valve should be commanded to close.

 

• Digital Input 14 (13/15)

(DI14) Field Shutdown will be used to determine if the block valve should be commanded to close.

 

• Digital Input 15 (14/15)

(DI15) Thrust Chamber Oil Flow will be used to determine if the block valve should be commanded to close.

 

• Digital Input 16 (15/15)

(DI16) Multipurpose will be used to determine if the block valve should be commanded to close.

 

Block Valve – Independent Close Conditions > When To Close 1

Block Valve – Independent Close Conditions > When To Close 2

Block Valve – Independent Close Conditions > When To Close 3

Block Valve – Independent Close Conditions > When To Close 4

When an analog input has been selected as an Close Source, the When To Close value also needs to be configured. When To Close determines if the Close Source condition is met when the measured value is equal to or GREATER than the setpoint or when the measured value is equal to or LESS than the setpoint.

• Equal or Greater (1/2)

The condition will be met if the measured value of the analog input is equal to or greater than the value of the associated setpoint.

 

• Equal or Less (2/2)

The condition will be met if the measured value of the analog input is equal to or less than the value of the associated setpoint.

When To Close is disabled when the associated Close Source is set to None or a digital input.

 

Block Valve – Independent Close Conditions > Close Setpoint 1

Block Valve – Independent Close Conditions > Close Setpoint 2

Block Valve – Independent Close Conditions > Close Setpoint 3

Block Valve – Independent Close Conditions > Close Setpoint 4

When an analog input has been selected as a Close Source, the Close Setpoint value also needs to be configured. The Close Setpoint is the scaled value of the analog input that must be met in order for the Close Source condition to be met. The Close Source condition can also be met if the scaled value of the analog input is greater than or less than the value of Close Setpoint, depending on how the associated When To Close parameter is configured.

Close Setpoint is disabled when the associated Close Source is set to None or a digital input.

 

 

Variable Frequency Drive

Configuration parameters related to the Variable Frequency Drive are available in:

Configure > Operation > Variable Frequency Drive

 

Variable Frequency Drive > Minimum Speed

Is the slowest speed that the system will operate at when in a run condition.  The only time that the system would not run at least at this minimum speed is because there is a current limit or torque limit being activated on the main motor of the system.  In this case it is common to see the speed of the motor not go above 2 – or 3Hz and occurs automatically to prevent the damage of the motor or the VFD.

 

Variable Frequency Drive > Maximum Speed

Is the maximum speed the system will run.  The only time the system can run faster than this value is if automatic regeneration protection mode is turned on and the system is experiencing an event that is causing a regenerative condition.  The speed increase is very temporary and will go away automatically when the regenerative condition goes away.  This setting can only be changed when the main pump motor is not running.

 

Variable Frequency Drive > Overload

The Overload setting is just what it sounds like.  This is the motor overload that you want set for the main pump motor.  This setting can be set to a maximum of either the motor FLA + its safety factor or the maximum running amperage the VFD in the panel is capable of (which ever value is lower).  It is recommended that the overload be set at least 4 or 5 amps over the motor nameplate FLA to avoid nuisance overload shutdown events.

 

Variable Frequency Drive > Current Limit

Variable Frequency Drive > Current Limit Setpoint

If current limit is enabled then the VFD in the panel will reduce the speed of the motor to automatically bring the current the motor is drawing below the set value the operator puts into Current Limit Setpoint.

 

Variable Frequency Drive - Advanced > Control Mode

The control mode has two possible settings of V/Hz (volts to hertz mode) and torque vector mode.  On an H-Pump it is extremely unlikely that torque vector mode will be needed or even helpful so leave this setting in V/Hz mode.  If torque vector mode is felt to be required then s special motor to VFD tuning process must be done.  If torque vector is desired contact the factory on how to perform the Auto-tuning procedure to allow torque vector mode to work correctly.

 

Variable Frequency Drive - Advanced > Torque Boost

Torque boost can be very beneficial on a hard starting system.  Torque boost will overexcite the motor by sending a higher level of voltage at a low speed when starting (starting only) to create extra low speed torque in the motor to get past the hard start.  If a torque boost is desired the starting point should not be too aggressive and 2.0 is a reasonable number to begin with.

 

Variable Frequency Drive - Advanced > Base Frequency

Base frequency is the motor driving speed that maximum available motor voltage will be applied to the motor.  Since the base speed of a 60Hz motor is at 60 Hz it is typical to leave this value at the default of 60Hz.  This setting can only be changed when the main pump motor is not running.

Variable Frequency Drive - Advanced > Maximum Voltage

Maximum voltage is the voltage that the VFD will put out to the motor when running at or above the base Frequency.  It is typical to leave this value at the default setting.  This setting can only be changed when the main pump motor is not running.

 

Variable Frequency Drive - Advanced > Carrier Frequency

The carrier frequency affects how smooth electrically the sine wave output from the VFD is to the motor.  The higher the number the smoother the sine wave is to the motor.  This should not be confused with motor harmonics or common mode current and does not relate to this at all.  The lower the carrier frequency the lower the heat generation of your VFD will be.  The cooling system on the OptiPump HPS has been tuned to allow a maximum carrier frequency of 6.0.  If the system experience over heating issues in the installation lowering the carrier frequency from 6.0 to 4.0 or even 2.0 will make the system operate cooler.  The motor will accept all carrier frequencies but you will find audible noise coming from the motor gets stronger at lower carrier frequencies.  The higher level of audible noise does not hurt the motor, but may become a human issue if the installation is near a populated structure and noise is undesirable.

 

Variable Frequency Drive - Advanced > Regen Mode

Automatic regeneration control can be disabled, controlled by motor torque or controlled by VFD DC bus voltage.  If automatic regeneration is required then the operator must also set a value for the Regen Frequency.

 

Variable Frequency Drive - Advanced > Regen Frequency

Is the maximum amount of speed greater than what the current speed of the motor is to allow the system to try and automatically prevent regeneration.  So for example if this value were set to 10Hz then if the motor were running at 45 HZ and a regeneration event occurred then the system would allow the motor to automatically speed up to 55Hz to try and prevent the regeneration from creating a DC bus overvoltage shutdown condition.

 

Variable Frequency Drive - Advanced > Stop Mode

This setting is only effective when there is a stop command present to the VFD inside the OptiPump HPS system.  The setting of this value to coast to stop is the common setting and a stop command to the pump will simple cut off voltage to the motor and let the fluid pressure stop the pump.  If a controlled stop is desirable then set to Decelerate.  Deceleration will be controlled by what the operator sets for Decel Time. Setting the deceleration time too aggressively will essentially guarantee an overvoltage fault on the VFD every time the system stops.  So if decelerate is needed then do not set a short deceleration time.  Sometimes the system will be unable to reliably stop the motor with just deceleration and a special setting for DC injection braking is required.  Contact the factory if this is the case for your system for specialty settings.

Variable Frequency Drive - Advanced > Accel Time

This is the amount of time that the VFD will take to bring the main pump motor from a full stop to 100% speed.  So if the pump is already at 50% speed then it will take 1/2 the time set here to get from 50% to 100% speed.

 

Variable Frequency Drive - Advanced > Decel Time

This is the amount of time the VFD will take to bring the main motor from full speed to zero speed.

 

Motor

Configuration parameters related to the Motor are available in:

Configure > Operation > Motor

 

Motor > Rated Speed

Select the motor speed that closest matches your motors name plate speed.

 

Motor > Rated Horsepower

Enter in the nameplate horse power of your motor.

 

Motor > Full-Load Amps

Enter in the full load amps (FLA) from the nameplate of your motor (No safety factor or overload value here just the nameplate amps).

Pump Curve

Configuration parameters related to the Pump Curve are available in:

Configure > Pump Curve

 

The pump curve for the main pump is a critical component for the safe and reliable use of the system. The pump curve is responsible for defining the limits of the acceptable in-curve area that result in the best operational efficiency and longest life of the equipment.

When configuring the pump curve, the Pump Curve Profile screen will display the pump curve for the active profile. The x-axis is flow, while the y-axis is discharge pressure. The best efficiency point (BEP) at 60 Hz is displayed in the upper right corner of the plot, and marked with the intersecting red lines when used with the Custom Coefficients profile. Only one of the two profile buttons at the top of the screen will be active at a time, and is determined by the active profile selected using the Select Profile button in the upper left corner of the screen.

Depending on the complexity of the pump curve, the curve may require a short period of time to plot.

 

 

The OptiPump HPS controller supports two types of pump profiles, which are used to define the main pump curve. The active profile is displayed at the top of the screen, and the button is shown with a gray background when logged-in.

1. Custom Coefficients

For the more advanced operator, the pump curve can be defined using the coefficients for the pump curve equation, as well as setting the best operating point.

 

2. Custom 7-Point

The 7-point profile approximates the pump curve using 7 points. While simpler to understand than the custom coefficients profile, more parameters are required to define the approximate pump curve. The OptiPump HPS controller, however, helps simplify the process by automatically generating many of the parameters required to define the Tornado Plot bounds.

 

 

Custom Coefficients

Configuration parameters related to the Custom Coefficients Pump Curve Profile are available in:

Configure > Pump Curve > Custom Coefficients

 

When pump stages or pumps with known curve coefficients are used, the Custom Coefficients profile can provide more control over the process than a typical point approximation curve. However, the stage or pump coefficients must be known and entered manually. If the coefficients are unavailable, try requesting the specifications and factory test sheets for the pump, which may provide the information.

 

Custom Coefficients - General Specifications > Number of Stages

The number of the stages used in main pump.

 

Custom Coefficients - General Specifications > Fluid Specific Gravity

Enter the approximate specific gravity of the fluid being moved by the main pump.

Custom Coefficients - General Specifications > Curve Upper Tolerance

The upper tolerance defines the upper pump curve limit as a percentage of the current output frequency. The upper tolerance pump curve is calculated using the affinity laws to scale the 60 Hz pump curve to a faster speed. The up-scaled pump curve is then used to determine the upper limit discharge pressure based on the measured flow. If the measured discharge pressure exceeds the calculated upper limit, the main pump is considered to be running out-of-curve.

 

Custom Coefficients - General Specifications > Curve Lower Tolerance

The lower tolerance defines the lower pump curve limit as a percentage of the current output frequency. The lower tolerance pump curve is calculated using the affinity laws to scale the 60 Hz pump curve to a slower speed. The down-scaled pump curve is then used to determine the lower limit discharge pressure based on the measured flow. If the measured discharge pressure exceeds (goes below) the calculated lower limit, the main pump is considered to be running out-of-curve.

 

Custom Coefficients - Feet of Head Coefficients > Coefficient X...

Enter the feet of head (pressure) coefficients for a single pump curve stage. If the coefficients are provided for the overall pump, rather than a single stage within the pump, enter the coefficients, then a value of 1 for the Number of Stages configuration parameter.

 

Custom Coefficients - Feet of Head Coefficients > BEP Flow @ 60 Hz

Enter the best efficiency point (BEP) flow at 60 Hz for the main pump.

 

Custom Coefficients - Feet of Head Coefficients > BEP Minimum Flow @ 60 Hz

Enter the best efficiency point (BEP) minimum flow at 60 Hz for the main pump. The BEP minimum flow point is used to create the upper boundary of the Tornado Plot funnel.

 

Custom Coefficients - Feet of Head Coefficients > BEP Maximum Flow @ 60 Hz

Enter the best efficiency point (BEP) maximum flow at 60 Hz for the main pump. The BEP maximum flow point is used to create the lower boundary of the Tornado Plot funnel.

Custom Coefficients - Feet of Head Coefficients > Plot Minimum Flow

Occasionally, the pump curve coefficients do not accurately reflect performance outside a set range of flow rates. The Plot Minimum Flow value sets the minimum flow rate to use when plotting the pump curve and Tornado Plot. The minimum value is often 0 BPD, and a good starting point if the value is unknown.

 

Custom Coefficients - Feet of Head Coefficients > Plot Maximum Flow

Occasionally, the pump curve coefficients do not accurately reflect performance outside a set range of flow rates. The Plot Maximum Flow value sets the maximum flow rate to use when plotting the pump curve and Tornado Plot. Unfortunately, no common maximum flow rate value exists, so using slightly more than the BEP Maximum Flow @ 60 Hz value can be a good starting point if the value is unknown.

 

Custom 7-Point

Configuration parameters related to the Custom 7-Point Pump Curve Profile are available in:

Configure > Pump Curve > Custom 7-Point

 

When detailed information about the main pump is unavailable, or the main pump has become worn, the Custom 7-Point profile can be used to approximate the performance curve. The profile uses 7 operator-defined points at increasing speeds to set the flow and pressure along the best efficiency curve. Since each point can be individually set by the operator, performance can be tailored for the characteristics of the equipment at the site. The boundaries of the Tornado Plot can also be operator-defined, though the numerous values that are required can be tedious to enter. The OptiPump HPS controller includes a feature to automatically set the Tornado Plot boundaries to simplify the process and provide good starting points for customization.

 

Custom 7-Point - General Specifications > Curve Lower Tolerance

The lower tolerance defines the lower pump curve limit as a percentage of the current output frequency. The lower tolerance pump curve is calculated using the affinity laws to scale the 60 Hz pump curve to a slower speed. The down-scaled pump curve is then used to determine the lower limit discharge pressure based on the measured flow. If the measured discharge pressure exceeds (goes below) the calculated lower limit, the main pump is considered to be running out-of-curve.

 

Custom 7-Point - General Specifications > Curve Upper Tolerance

The upper tolerance defines the upper pump curve limit as a percentage of the current output frequency. The upper tolerance pump curve is calculated using the affinity laws to scale the 60 Hz pump curve to a faster speed. The up-scaled pump curve is then used to determine the upper limit discharge pressure based on the measured flow. If the measured discharge pressure exceeds the calculated upper limit, the main pump is considered to be running out-of-curve.

 

Custom 7-Point - Control Curve > Points

Enter the desired speed for Points 1 through 6, and the associated target discharge pressure and flow rate associated with each speed. Point 7 is fixed at 60 Hz, so refer to the pump datasheet, if available, for the best efficiency point (BEP) at 60 Hz values.

 

Custom 7-Point - Tornado Plot Bounds > Points

The points defined for the Tornado Plot bounds define the upper and lower boundaries of the tornado funnel. Due to the large number of configuration parameters associated with these points, the Generate Auto-Bounds feature is highly recommended.

 

Custom 7-Point - Tornado Plot Bounds > Auto-Bounds Range

The large number of configurable parameters associated with the Tornado Plot bounds can be tedious to configure by hand through some trial and error. The OptiPump HPS controller can automatically generate typical Tornado Plot bounds using the Generate Auto-Bounds feature. The Auto-Bounds Range sets the percent tolerance around the Control Curve Points for the pressure and flow values.

To use the Generate Auto-Bounds feature, enter a value for Auto-Bounds Range (the smaller the value, the narrower the Tornado Plot funnel), then press and hold the Generate Auto-Bounds button for 5 seconds. When the Generate-Auto Bounds button is pressed, a countdown timer will appear and the controller will begin calculating the points. When the timer reaches zero and the green status "Done" appears, the process is complete. To see the newly generated pump curve with Tornado Plot bounds, press the Back button to return the Pump Curve screen.

 

Analog Inputs

Configuration parameters related to the analog inputs are available in:

Configure > Analog Ins

 

Analog inputs available to the operator include:

• 13 4-20 mA
• 1 J-Type Thermocouple
• 8 100-Ohm Platinum RTD (α=0.0385)

 

The analog inputs are connected to 5 different controller I/O modules. I/O module wiring is indicated for each individual input on subsequent pages.

 

Note: 

When installed in a panel provided by Advanced Industrial Devices, the analog and digital inputs and outputs may be prewired to terminals mounted inside the panel or in a field device wiring hip-box. In this case, please refer to the wiring diagram included with the panel for field device connection locations.

The analog inputs for the OptiPump HPS controller are designed to be highly flexible and customizable by the operator to meet the needs of a site without requiring custom firmware. Several analog inputs have a dedicated function, as well as fixed units. However, in general, the names and units of most of the analog inputs are customizable by the operator. For analog inputs that have a fixed function or other fixed parameters, a note will appear on the configuration screen informing the operator of the options available.

 

Scale Minimum, Scale Maximum, Units

The operator can configure the analog input minimum and maximum scaling of the sensor.  In addition the setting can be made for the system to shut down or ignore a sensor failure.

The math conversion for the units is not automatically performed for the operator and any conversions required to change the units from the sensor to match the units on the screen must be done by the operator and input on the settings screen for that analog input.

Example:  1 PSI = 2.31 Feet, so if a 0-10 PSI sensor is being used for a tank level measurement, then the minimum sensor range would be 0 and the maximum sensor range would be 10 x 2.31 = 23.1 Feet.

 

Reactions

 

All 4 setpoint reactions can be individually configured as one of the following:

 

• Disabled (1/3)

The setpoint value will be ignored.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Setpoints

There are four setpoints available for this analog input and they are:

• High-High Setpoint
• High Setpoint
• Low Setpoint
• Low-Low Setpoint

Start Delay

Is a setting that the system will wait for the unit to be running and then after a run condition has been met will wait for the timer to run out before ever looking for an alarm/shutdown condition on that analog input.  Once the start delay time is complete it will not be used again until the next system start.

 

Detection Delay

After the start delay is complete the system will then look at the detection delay.  If an Alarm/Shutdown condition is held for the amount of time in this setting then the system will either alarm or shutdown.

 

Restart Type

• Manual (1/2)

If on shutdown the operator wants the system to require a positive action to force a reset then a manual restart is what is needed.

 

• Timed (2/2)

If the operator wants the shutdown to automatically reset itself when/if the shutdown condition clears then set an automatic reset and set an appropriate restart delay.

 

Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

(AI1) Suction Pressure

Configuration parameters related to Analog Input 1 are available in:

Configure > Analog Ins > Analog Input 1

 

The function of Analog Input 1 is dedicated to the suction pressure of the main pump. Both the name and units can be modified by the operator.

The 4-20ma signal is connected to terminal AI0 on the I/O module labeled IO-D16A3-TO16.

 

(AI2) Discharge Pressure

Configuration parameters related to Analog Input 2 are available in:

Configure > Analog Ins > Analog Input 2

 

The function of Analog Input 2 is dedicated to the discharge pressure of the main pump. The name can be modified by the operator, but the units are fixed and must be scaled in PSI.

The 4-20ma signal is connected to terminal AI1 on the I/O module labeled IO-D16A3-TO16.

 

(AI3) Tank Level

Configuration parameters related to Analog Input 3 are available in:

Configure > Analog Ins > Analog Input 3

 

The function of Analog Input 3 is dedicated to the tank level that can control both the start/stop and speed of the main pump. The name can be modified by the operator, as well as the units.

The 4-20ma signal is connected to terminal AI2 on the I/O module labeled IO-D16A3-TO16.

 

Analog Input 3 > Tank Status

Analog Input 3 can be assigned to any of the 6 tanks shown on the Tanks status screen. If Tank Status is set to Disabled, Analog Input 3 will not be assigned to any of the tanks on the Tanks status screen, but will still be shown as the main tank on the Home screen.

When assigning analog inputs to tanks on the Tanks status screen, be sure to assign only ONE analog input per tank.

• Disabled (1/7)

Analog Input 3 will not be shown on the Tanks status screen, but will still be shown as the main tank on the Home screen.

 

• Tank 1 (2/7)

Analog Input 3 will be shown as Tank 1 on the Tanks status screen.

 

• Tank 2 (3/7)

Analog Input 3 will be shown as Tank 2 on the Tanks status screen.

 

• Tank 3 (4/7)

Analog Input 3 will be shown as Tank 3 on the Tanks status screen.

 

• Tank 4 (5/7)

Analog Input 3 will be shown as Tank 4 on the Tanks status screen.

 

• Tank 5 (6/7)

Analog Input 3 will be shown as Tank 5 on the Tanks status screen.

 

• Tank 6 (7/7)

Analog Input 3 will be shown as Tank 6 on the Tanks status screen.

 

 

(AI4) Well Casing Pressure

Configuration parameters related to Analog Input 4 are available in:

Configure > Analog Ins > Analog Input 4

 

The 4-20ma signal is connected to terminal T+/AN of group 0 on the I/O module labeled IO-ATC8.

 

 

(AI5) Wellhead Pressure

Configuration parameters related to Analog Input 5 are available in:

Configure > Analog Ins > Analog Input 5

 

The function of Analog Input 5 is dedicated to the wellhead/pipeline pressure, as show on the flow diagram on the Home screen. The name can be modified by the operator, as well as the units.

The 4-20ma signal is connected to terminal T+/AN of group 1 on the I/O module labeled IO-ATC8.

 

(AI6) Thrst Chmbr Vib

Configuration parameters related to Analog Input 6 are available in:

Configure > Analog Ins > Analog Input 6

 

The 4-20ma signal is connected to terminal T+/AN of group 2 on the I/O module labeled IO-ATC8.

 

 

(AI7) Discharge Flow

Configuration parameters related to Analog Input 7 are available in:

Configure > Analog Ins > Analog Input 7

 

The function of Analog Input 7 is dedicated to the discharge flow rate of the main pump. The name can be modified by the operator. However, the units are fixed in barrels per day (BPD), as required for the automatic operation of the pressure control valve and pump curve.

The 4-20ma signal is connected to terminal T+/AN of group 3 on the I/O module labeled IO-ATC8.

 

Analog Input 7 > Flow Source

• Analog (AI7) (1/2)

If a flow meter is installed, Analog Input 7 will be used to measure the flow rate. The Scale Minimum and Scale Maximum parameters must be configured.

 

• Calculated (2/2)

If a flow meter is NOT installed, a calculated value for the estimated flow rate will be used. The calculated flow rate is based on the pump curve configured in Configure > Pump Curve. When set to Calculated, the Scale Minimum and Scale Maximum parameters do NOT affect the value, and are not required to be set.

 

 

(AI8) Auxiliary Flow

Configuration parameters related to Analog Input 8 are available in:

Configure > Analog Ins > Analog Input 8

 

The function of Analog Input 8 is not dedicated, but does support an additional parameter and expanded scaling, as compared to the other analog inputs, that allows for the use for a second, auxiliary flow meter. 

The 4-20ma signal is connected to terminal T+/AN of group 4 on the I/O module labeled IO-ATC8.

 

Analog Input 8 > Flow Totalizer

When used as a flow input, the flow may optionally be totalized, similar to (AI7) Discharge Flow. When the totalizing feature is enabled, barrels per day (BPD) are the recommended units.

• Disabled (1/2)

The flow totalizer is not used, and will be hidden on the Metrics Overview screen.

 

• Enabled (2/2)

The flow totalizer will accumulate and track the total flow for the current and previous days, and will be shown on the Metrics Overview screen.

 

 

(AI9) Prsr Ctrl Valve Pos

Configuration parameters related to Analog Input 9 are available in:

Configure > Analog Ins > Analog Input 9

 

The function of Analog Input 9 is dedicated to the feedback of the pressure control valve position. The name can be modified by the operator, but the units are fixed and must be scaled in percent.

The 4-20ma signal is connected to terminal T+/AN of group 5 on the I/O module labeled IO-ATC8.

 

(AI10/16) Thrst Chmbr Oil Temp

Configuration parameters related to Analog Input 10 (J-Type Thermocouple) and Analog Input 16 (RTD) are available in:

Configure > Analog Ins > Analog Input 10/16

 

The function of Analog Input 10 and Analog Input 16 are both dedicated to the thrust chamber oil temperature. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit. However, only one of these analog inputs may be used at a time. Analog Input 10 is used when a J-type thermocouple is used to measure the thrust chamber oil temperature. Analog Input 16 is used when a RTD is used to measure the thrust chamber oil temperature.

Pressing the Modify button on the Configure > Analog Ins screen for either Analog Input 10 or Analog Input 16 will load the same configuration page shown above.

 

 

Analog Input 10/16 > Temperature Source

Analog Input 10 and Analog Input 16 have the same purpose, but use two different temperature sensing types. The operator must select the sensor type installed.

• J-Type TC (AI10) (1/2)

The thermocouple is connected to the I/O module labeled IO-ATC8. The red, insulated thermocouple wire is connected to terminal T-. The white thermocouple wire is connected to terminal T+.

 

 

• RTD (AI16) (2/2)

If the operator selects the use of a 100 ohm platinum RTD, with alpha = 0.0385, the sensor connection will NOT USE I/O module labeled IO-ATC8. The sensor will connect instead to the first of the IO-PT400 modules in the string of controller modules in group CH0.  A 100 ohm RTD will have either 3 or 4 wires to connect depending on the make and model.  If the RTD does not have 3 or 4 wires, the sensor is likely NOT a 100 ohm RTD or a RTD to 4-20ma converter is installed in the temperature sensor and cannot be connected to either location shown here. 

 

For a 3-wire, 100 ohm RTD connection, the two white wires connect to terminal I+ and V+ and the red wire connects to terminal V- with a jumper wire connecting terminals V- and I-.  For a 4-wire, 100 ohm RTD connection, the two white wires connect to terminals I+ and V+ and the two red wires connect to terminals V- and I-.

A typical 3-wire, 100 ohm RTD connection is shown below.

 

 

(AI11) Signal-Following Cmd

Configuration parameters related to Analog Input 11 are available in:

Configure > Analog Ins > Analog Input 11

 

The function of Analog Input 11 is not dedicated, but can be used as an external speed command. For example, Analog Input 11 can be used to receive a speed command from another site controller. The name can be modified by the operator, as well as the units.

The 4-20ma signal is connected to terminal T+/AN of group 7 on the I/O module labeled IO-ATC8.

 

Analog Input 11 > Tank Status

Analog Input 11 can be assigned to any of the 6 tanks shown on the Tanks status screen. If Tank Status is set to Disabled, Analog Input 11 will not be assigned to any of the tanks on the Tanks status screen. 

When assigning analog inputs to tanks on the Tanks status screen, be sure to assign only ONE analog input per tank.

• Disabled (1/7)

Analog Input 11 will not be shown on the Tanks status screen.

 

• Tank 1 (2/7)

Analog Input 11 will be shown as Tank 1 on the Tanks status screen.

 

• Tank 2 (3/7)

Analog Input 11 will be shown as Tank 2 on the Tanks status screen.

 

• Tank 3 (4/7)

Analog Input 11 will be shown as Tank 3 on the Tanks status screen.

 

• Tank 4 (5/7)

Analog Input 11 will be shown as Tank 4 on the Tanks status screen.

 

• Tank 5 (6/7)

Analog Input 11 will be shown as Tank 5 on the Tanks status screen.

 

• Tank 6 (7/7)

Analog Input 11 will be shown as Tank 6 on the Tanks status screen.

 

 

(AI12) Mtr Brng In Vib

Configuration parameters related to Analog Input 12 are available in:

Configure > Analog Ins > Analog Input 12

 

The 4-20ma signal is connected to terminal I of group AI0 on the I/O module labeled IO-AI4-AO2.

 

Analog Input 12 > Tank Status

Analog Input 12 can be assigned to any of the 6 tanks shown on the Tanks status screen. If Tank Status is set to Disabled, Analog Input 12 will not be assigned to any of the tanks on the Tanks status screen. 

When assigning analog inputs to tanks on the Tanks status screen, be sure to assign only ONE analog input per tank.

• Disabled (1/7)

Analog Input 12 will not be shown on the Tanks status screen.

 

• Tank 1 (2/7)

Analog Input 12 will be shown as Tank 1 on the Tanks status screen.

 

• Tank 2 (3/7)

Analog Input 12 will be shown as Tank 2 on the Tanks status screen.

 

• Tank 3 (4/7)

Analog Input 12 will be shown as Tank 3 on the Tanks status screen.

 

• Tank 4 (5/7)

Analog Input 12 will be shown as Tank 4 on the Tanks status screen.

 

• Tank 5 (6/7)

Analog Input 12 will be shown as Tank 5 on the Tanks status screen.

 

• Tank 6 (7/7)

Analog Input 12 will be shown as Tank 6 on the Tanks status screen.

 

 

(AI13) Mtr Brng Out Vib

Configuration parameters related to Analog Input 13 are available in:

Configure > Analog Ins > Analog Input 13

 

The 4-20ma signal is connected to terminal I of group AI1 on the I/O module labeled IO-AI4-AO2.

 

Analog Input 13 > Tank Status

Analog Input 13 can be assigned to any of the 6 tanks shown on the Tanks status screen. If Tank Status is set to Disabled, Analog Input 13 will not be assigned to any of the tanks on the Tanks status screen. 

When assigning analog inputs to tanks on the Tanks status screen, be sure to assign only ONE analog input per tank.

• Disabled (1/7)

Analog Input 13 will not be shown on the Tanks status screen.

 

• Tank 1 (2/7)

Analog Input 13 will be shown as Tank 1 on the Tanks status screen.

 

• Tank 2 (3/7)

Analog Input 13 will be shown as Tank 2 on the Tanks status screen.

 

• Tank 3 (4/7)

Analog Input 13 will be shown as Tank 3 on the Tanks status screen.

 

• Tank 4 (5/7)

Analog Input 13 will be shown as Tank 4 on the Tanks status screen.

 

• Tank 5 (6/7)

Analog Input 13 will be shown as Tank 5 on the Tanks status screen.

 

• Tank 6 (7/7)

Analog Input 13 will be shown as Tank 6 on the Tanks status screen.

 

 

(AI14) Auxiliary Tank 1 Lvl

Configuration parameters related to Analog Input 14 are available in:

Configure > Analog Ins > Analog Input 14

 

The 4-20ma signal is connected to terminal I of group AI2 on the I/O module labeled IO-AI4-AO2.

 

Analog Input 14 > Tank Status

Analog Input 14 can be assigned to any of the 6 tanks shown on the Tanks status screen. If Tank Status is set to Disabled, Analog Input 14 will not be assigned to any of the tanks on the Tanks status screen. 

When assigning analog inputs to tanks on the Tanks status screen, be sure to assign only ONE analog input per tank.

• Disabled (1/7)

Analog Input 14 will not be shown on the Tanks status screen.

 

• Tank 1 (2/7)

Analog Input 14 will be shown as Tank 1 on the Tanks status screen.

 

• Tank 2 (3/7)

Analog Input 14 will be shown as Tank 2 on the Tanks status screen.

 

• Tank 3 (4/7)

Analog Input 14 will be shown as Tank 3 on the Tanks status screen.

 

• Tank 4 (5/7)

Analog Input 14 will be shown as Tank 4 on the Tanks status screen.

 

• Tank 5 (6/7)

Analog Input 14 will be shown as Tank 5 on the Tanks status screen.

 

• Tank 6 (7/7)

Analog Input 14 will be shown as Tank 6 on the Tanks status screen.

 

 

(AI15) Auxiliary Tank 2 Lvl

Configuration parameters related to Analog Input 15 are available in:

Configure > Analog Ins > Analog Input 15

 

The 4-20ma signal is connected to terminal I of group AI3 on the I/O module labeled IO-AI4-AO2.

 

Analog Input 15 > Tank Status

Analog Input 15 can be assigned to any of the 6 tanks shown on the Tanks status screen. If Tank Status is set to Disabled, Analog Input 15 will not be assigned to any of the tanks on the Tanks status screen. 

When assigning analog inputs to tanks on the Tanks status screen, be sure to assign only ONE analog input per tank.

• Disabled (1/7)

Analog Input 15 will not be shown on the Tanks status screen.

 

• Tank 1 (2/7)

Analog Input 15 will be shown as Tank 1 on the Tanks status screen.

 

• Tank 2 (3/7)

Analog Input 15 will be shown as Tank 2 on the Tanks status screen.

 

• Tank 3 (4/7)

Analog Input 15 will be shown as Tank 3 on the Tanks status screen.

 

• Tank 4 (5/7)

Analog Input 15 will be shown as Tank 4 on the Tanks status screen.

 

• Tank 5 (6/7)

Analog Input 15 will be shown as Tank 5 on the Tanks status screen.

 

• Tank 6 (7/7)

Analog Input 15 will be shown as Tank 6 on the Tanks status screen.

 

 

(AI17) Mtr Winding 1 Temp

Configuration parameters related to Analog Input 17 are available in:

Configure > Analog Ins > Analog Input 17

 

Analog Input 17 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the first of these modules. The sensor is connected to terminals +I, +V, -V in group CH1. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

(AI18) Mtr Winding 2 Temp

Configuration parameters related to Analog Input 18 are available in:

Configure > Analog Ins > Analog Input 18

 

Analog Input 18 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the first of these modules. The sensor is connected to terminals +I, +V, -V in group CH2. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

(AI19) Mtr Winding 3 Temp

Configuration parameters related to Analog Input 19 are available in:

Configure > Analog Ins > Analog Input 19

 

Analog Input 19 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the first of these modules. The sensor is connected to terminals +I, +V, -V in group CH3. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

(AI20) Motor Bearing Front Temperature

Configuration parameters related to Analog Input 20 are available in:

Configure > Analog Ins > (AI20) Motor Bearing Front Temperature

 

Analog Input 20 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the second of these modules. The sensor is connected to terminals +I, +V, -V in group CH0. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

(AI21) Mtr Brng Rear Temp

Configuration parameters related to Analog Input 21 are available in:

Configure > Analog Ins > Analog Input 21

 

Analog Input 21 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the second of these modules. The sensor is connected to terminals +I, +V, -V in group CH1. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

(AI22) Pump Housing Temp

Configuration parameters related to Analog Input 22 are available in:

Configure > Analog Ins > Analog Input 22

 

Analog Input 22 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the second of these modules. The sensor is connected to terminals +I, +V, -V in group CH2. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

(AI23) Ambient Temp

Configuration parameters related to Analog Input 23 are available in:

Configure > Analog Ins > Analog Input 23

 

Analog Input 23 is dedicated to measuring a temperature with a RTD sensor. The name can be modified by the operator, but the units are fixed in degrees Fahrenheit.

A 100 ohm RTD signal wire is connected to the I/O module labeled IO-PT400 and is the second of these modules. The sensor is connected to terminals +I, +V, -V in group CH3. Refer to Configure > Analog Ins > Analog Input 10/16 for more information on connect a RTD sensor.

 

Filter Differential Pressure

Configuration parameters related to the Filter Differential Pressure are available in:

Configure > Analog Ins > Filter Differential Pressure

 

The filter differential pressure is based on two sensors.  The operator must select a combination of two sensors to enable this feature. The filter differential pressure is calculated by subtracting the outlet pressure from the inlet pressure.

Both of the selected analog inputs must be scaled in PSI.

Filter Differential Pressure > Inlet Analog Input

The analog input used to measure the pressure at the inlet of the filter.

• Analog Input 1 (1/7)
• Analog Input 3 (2/7)
• Analog Input 11 (3/7)
• Analog Input 12 (4/7)
• Analog Input 13 (5/7)
• Analog Input 14 (6/7)
• Analog Input 15 (7/7)

 

Filter Differential Pressure > Outlet Analog Input

The analog input used to measure the pressure at the outlet of the filter.

• Analog Input 1 (1/7)
• Analog Input 3 (2/7)
• Analog Input 11 (3/7)
• Analog Input 12 (4/7)
• Analog Input 13 (5/7)
• Analog Input 14 (6/7)
• Analog Input 15 (7/7)

 

Note:
If one of the two analog inputs selected is Analog Input 3 (2/7) (the main tank level), the input must be rescaled to PSI, as the tank level is typically scaled in feet. Use the following two configuration parameters to rescale (AI3) Tank Level internally for use with the filter differential pressure. This rescaling does NOT affect the parameters on the Configure > Analog Ins > Analog Input 3 screen.

 

Filter Differential Pressure - Tank Level - Analog Input 3 - PSI Rescale > Scale Minimum (4mA)

Pressure value in PSI measured by the transducer connected to Analog Input 3 at 4 mA.

 

Filter Differential Pressure - Tank Level - Analog Input 3 - PSI Rescale > Scale Minimum (20mA)

Pressure value in PSI measured by the transducer connected to Analog Input 3 at 20 mA.

 

Digital Inputs

Configuration parameters related to the digital inputs are available in:

Configure > Digital Ins

 

The digital inputs are connected to a single controller I/O module. Most digital inputs have a dedicated purpose, but can be renamed by the operator in order to tailor the controller configuration to the site requirements.

Digital inputs are on/off, dry-contact, switch inputs that are either open or closed.

 

 

 

(DI1) Hand

Configuration parameters related to Digital Input 1 are available in:

Configure > Digital Ins > Digital Input 1

 

The function of Digital Input 1 is dedicated to the Hand function of the HOA switch. The name can be modified by the operator.

 

Digital Input 1 > Active When

Determines when the digital input is considered to be active and to perform the assigned function.

• Contact Open (1/2)

The digital input will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input will be active when the contact to the input is closed.

 

Digital Input 1 > Active Delay

The amount of time required for the input to be open or closed before activating the function. This feature can be used to debounce the input.

(DI2) Auto

Configuration parameters related to Digital Input 2 are available in:

Configure > Digital Ins > Digital Input 2

 

The function of Digital Input 2 is dedicated to the Auto function of the HOA switch. The name can be modified by the operator.

 

Digital Input 2 > Active When

Determines when the digital input is considered to be active and to perform the assigned function.

• Contact Open (1/2)

The digital input will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input will be active when the contact to the input is closed.

 

Digital Input 2 > Active Delay

The amount of time required for the input to be open or closed before activating the function. This feature can be used to debounce the input.

(DI3) User Start

Configuration parameters related to Digital Input 3 are available in:

Configure > Digital Ins > Digital Input 3

 

The function of Digital Input 3 is dedicated to the User Start function. The User Start function allows a remote start signal from external equipment to act as a permissive when running in Auto. Refer to Configure > Operation > Main Pump - Start/Stop for more information. The name can be modified by the operator.

 

Digital Input 3 > Active When

Determines when the digital input is considered to be active and to perform the assigned function.

• Contact Open (1/2)

The digital input will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input will be active when the contact to the input is closed.

Digital Input 3 > Active Delay

The amount of time required for the input to be open or closed before activating the function. This feature can be used to debounce the input.

 

 

(DI4) Tank Level Start

Configuration parameters related to Digital Input 4 are available in:

Configure > Digital Ins > Digital Input 4

 

The function of Digital Input 4 is dedicated to Tank Level Start. Depending on the configuration, Digital Input 4 can control the starting and stopping of the system in Auto mode. Refer to Configure > Operation > Main Pump - Start/Stop for more information. The name can be modified by the operator.

 

Digital Input 4 > Active When

Determines when the digital input is considered to be active and to perform the assigned function.

• Contact Open (1/2)

The digital input will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input will be active when the contact to the input is closed.

Digital Input 4 > Active Delay

The amount of time required for the input to be open or closed before activating the function. This feature can be used to debounce the input.

 

 

(DI5) Tank Level Stop

Configuration parameters related to Digital Input 5 are available in:

Configure > Digital Ins > Digital Input 5

 

The function of Digital Input 5 is dedicated to Tank Level Stop. Depending on the configuration, Digital Input 5 can control the starting and stopping of the system in Auto mode. Refer to Configure > Operation > Main Pump - Start/Stop for more information. The name can be modified by the operator.

 

Digital Input 5 > Active When

Determines when the digital input is considered to be active and to perform the assigned function.

• Contact Open (1/2)

The digital input will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input will be active when the contact to the input is closed.

Digital Input 5 > Active Delay

The amount of time required for the input to be open or closed before activating the function. This feature can be used to debounce the input.

 

 

(DI6) TC Oil Pmp Run Cnfrm

Configuration parameters related to Digital Input 6 are available in:

Configure > Digital Ins > Digital Input 6

 

The function of Digital Input 6 is dedicated to the run confirmation of the thrust chamber oil pump. When used on a system with a thrust chamber oil pump, Digital Input 6 is used to provide feedback to the controller that the thrust chamber oil pump is actively running. Refer to Configure > Operation > Support Pumps - Thrust Chamber Oil Pump for more information. The name can be modified by the operator.

Note:
If the system was purchased with a thrust chamber oil pump motor starter pre-installed, this connection will be pre-wired to the motor starter auxiliary contact.

 

 

Digital Input 6 > Confirm When

Determines when the digital input is considered to be active and to confirm that the thrust chamber oil pump is actively running.

• Contact Open (1/2)

The thrust chamber oil pump is actively running when the contact to the input is open.

 

• Contact Closed (2/2)

The thrust chamber oil pump is actively running when the contact to the input is closed.

 

Digital Input 6 > Confirm Delay

The amount of time required for the input to be open or closed before confirming that the thrust chamber oil pump is actively running. This feature can be used to debounce the input.

 

 

(DI7) Chrg Pmp Run Cnfrm

Configuration parameters related to Digital Input 7 are available in:

Configure > Digital Ins > Digital Input 7

 

The function of Digital Input 7 is dedicated to the run confirmation of charge pump. When used on a system with a charge pump, Digital Input 7 is used to provide feedback to the controller that the charge pump is actively running. Refer to Configure > Operation > Support Pumps - Charge Pump for more information. The name can be modified by the operator.

Note:
If the system was purchased with a charge pump motor starter pre-installed, this connection will be pre-wired to the motor starter auxiliary contact.

 

 

Digital Input 7 > Confirm When

Determines when the digital input is considered to be active and to confirm that the charge pump is actively running.

• Contact Open (1/2)

The charge pump is actively running when the contact to the input is open.

 

• Contact Closed (2/2)

The charge pump is actively running when the contact to the input is closed.

 

Digital Input 7 > Confirm Delay

The amount of time required for the input to be open or closed before confirming that the charge pump is actively running. This feature can be used to debounce the input.

 

 

(DI8) Prsr Ctrl Valve Clsd

Configuration parameters related to Digital Input 8 are available in:

Configure > Digital Ins > Digital Input 8

 

The function of Digital Input 8 is dedicated to the closed confirmation of the pressure control valve. When used on a system with pressure control valve position indication contacts, Digital Input 8 is used to provide feedback to the controller that the pressure control valve is in the fully closed position. Refer to Configure > Operation > Pressure Control Valve for more information. The name can be modified by the operator.

Note:
Not all installations have pressure control valve position indication contacts available. Be sure to refer to the documentation or contact the manufacturer of the pressure control valve to verify proper installation.

 

 

Digital Input 8 > Confirm When

Determines when the digital input is considered to be active and to confirm that the pressure control valve is in the fully closed position.

• Contact Open (1/2)

The pressure control valve is currently in the fully closed position when the contact to the input is open.

 

• Contact Closed (2/2)

The pressure control valve is currently in the fully closed position when the contact to the input is closed.

 

Digital Input 8 > Confirm Delay

The amount of time required for the input to be open or closed before confirming that the pressure control valve is in the fully closed position. This feature can be used to debounce the input.

 

 

(DI9) Block Valve Clsd

Configuration parameters related to Digital Input 9 are available in:

Configure > Digital Ins > Digital Input 9

 

The function of Digital Input 9 is dedicated to the closed confirmation of the block valve. When used on a system with a block valve, Digital Input 9 is used to provide feedback to the controller that the block valve is in the fully closed position. Refer to Configure > Operation > Block Valve for more information. The name can be modified by the operator.

Note:
Not all installations use a block valve (a block valve is another valve, separate from the pressure control valve). Be sure to refer to the documentation or contact the manufacturer for the block valve, if installed, to verify proper installation.

 

 

Digital Input 9 > Confirm When

Determines when the digital input is considered to be active and to confirm that the block valve is in the fully closed position.

• Contact Open (1/2)

The block valve is currently in the fully closed position when the contact to the input is open.

 

• Contact Closed (2/2)

The block valve is currently in the fully closed position when the contact to the input is closed.

 

Digital Input 9 > Confirm Delay

The amount of time required for the input to be open or closed before confirming that the block valve is in the fully closed position. This feature can be used to debounce the input.

 

(DI10) Block Valve Open

Configuration parameters related to Digital Input 10 are available in:

Configure > Digital Ins > Digital Input 10

 

The function of Digital Input 10 is dedicated to the open confirmation of the block valve. When used on a system with a block valve, Digital Input 10 is used to provide feedback to the controller that the block valve is in the fully open position. Refer to Configure > Operation > Block Valve for more information. The name can be modified by the operator.

Note:
Not all installations use a block valve (a block valve is another valve, separate from the pressure control valve). Be sure to refer to the documentation or contact the manufacturer for the block valve, if installed, to verify proper installation.

 

 

(DI10) Block Valve Open > Confirm When

Determines when the digital input is considered to be active and to confirm that the block valve is in the fully open position.

• Contact Open (1/2)

The block valve is currently in the fully open position when the contact to the input is open.

 

• Contact Closed (2/2)

The block valve is currently in the fully open position when the contact to the input is closed.

 

(DI10) Block Valve Open > Confirm Delay

The amount of time required for the input to be open or closed before confirming that the block valve is in the fully open position. This feature can be used to debounce the input.

 

(DI11) TC Oil Rsrvr Lvl Low

Configuration parameters related to Digital Input 11 are available in:

Configure > Digital Ins > Digital Input 11

 

Digital Input 11 does not have a dedicated function, but is configured to indicate a low level in the thrust chamber oil reservoir by default.  The name can be modified by the operator.

 

Digital Input 11 > Active When

Determines when the digital input is considered to be active.

• Contact Open (1/2)

The digital input indication will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input indication will be active when the contact to the input is closed.

 

Digital Input 11 > Active Delay

The amount of time required for the input to be open or closed before indicating that the digital input is active. This feature can be used to debounce the input.

 

Digital Input 11 > Reaction

• Disabled (1/3)

The input will be ignored. Use this option if the input will not be used.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Digital Input 11 > Start Delay

The amount of time the controller will wait for the main pump to be running before ever looking for an alarm/shutdown condition on the digital input.  Once the start delay time is complete it will not be used again until the next system start.

 

Digital Input 11 > Detection Delay

After the start delay is complete, the controller will then use the detection delay.  If an alarm/shutdown condition is present for the amount of time in this setting, the controller will set an alarm or shutdown event depending on the setting of Reaction.

 

Digital Input 11 > Restart Type

• Manual (1/2)

If a shutdown event occurs, a manual restart will require an operator to either locally or remotely, via SCADA, reset the shutdown event before the system will restart.

 

• Timed (2/2)

If a shutdown event occurs, a timed restart will automatically reset the shutdown event after the time set in Restart Delay.

Digital Input 11 > Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

(DI12) Thrst Chmbr Oil Lvl Low

Configuration parameters related to Digital Input 12 are available in:

Configure > Digital Ins > Digital Input 12

 

Digital Input 12 does not have a dedicated function, but is configured to indicate a low oil level in the thrust chamber by default. The name can be modified by the operator.

 

Digital Input 12 > Active When

Determines when the digital input is considered to be active.

• Contact Open (1/2)

The digital input indication will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input indication will be active when the contact to the input is closed.

 

Digital Input 11 > Active Delay

The amount of time required for the input to be open or closed before indicating that the digital input is active. This feature can be used to debounce the input.

 

Digital Input 12 > Reaction

• Disabled (1/3)

The input will be ignored. Use this option if the input will not be used.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Digital Input 12 > Start Delay

The amount of time the controller will wait for the main pump to be running before ever looking for an alarm/shutdown condition on the digital input.  Once the start delay time is complete it will not be used again until the next system start.

 

Digital Input 12 > Detection Delay

After the start delay is complete, the controller will then use the detection delay.  If an alarm/shutdown condition is present for the amount of time in this setting, the controller will set an alarm or shutdown event depending on the setting of Reaction.

 

Digital Input 12 > Restart Type

• Manual (1/2)

If a shutdown event occurs, a manual restart will require an operator to either locally or remotely, via SCADA, reset the shutdown event before the system will restart.

 

• Timed (2/2)

If a shutdown event occurs, a timed restart will automatically reset the shutdown event after the time set in Restart Delay.

Digital Input 12 > Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

(DI13) Tank Level High

Configuration parameters related to Digital Input 13 are available in:

Configure > Digital Ins > Digital Input 13

 

Digital Input 13 does not have a dedicated function, but is configured to indicate a high tank level condition by default. The name can be modified by the operator.

 

Digital Input 13 > Active When

Determines when the digital input is considered to be active.

• Contact Open (1/2)

The digital input indication will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input indication will be active when the contact to the input is closed.

 

Digital Input 13 > Active Delay

The amount of time required for the input to be open or closed before indicating that the digital input is active. This feature can be used to debounce the input.

 

Digital Input 13 > Reaction

• Disabled (1/3)

The input will be ignored. Use this option if the input will not be used.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Digital Input 13 > Start Delay

The amount of time the controller will wait for the main pump to be running before ever looking for an alarm/shutdown condition on the digital input.  Once the start delay time is complete it will not be used again until the next system start.

 

Digital Input 13 > Detection Delay

After the start delay is complete, the controller will then use the detection delay.  If an alarm/shutdown condition is present for the amount of time in this setting, the controller will set an alarm or shutdown event depending on the setting of Reaction.

 

Digital Input 13 > Restart Type

• Manual (1/2)

If a shutdown event occurs, a manual restart will require an operator to either locally or remotely, via SCADA, reset the shutdown event before the system will restart.

 

• Timed (2/2)

If a shutdown event occurs, a timed restart will automatically reset the shutdown event after the time set in Restart Delay.

Digital Input 13 > Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

(DI14) Field Shutdown

Configuration parameters related to Digital Input 14 are available in:

Configure > Digital Ins > Digital Input 14

 

Digital Input 14 does not have a dedicated function, but is configured to indicate a general purpose field shutdown by default. The name can be modified by the operator.

 

Digital Input 14 > Active When

Determines when the digital input is considered to be active.

• Contact Open (1/2)

The digital input indication will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input indication will be active when the contact to the input is closed.

 

Digital Input 14 > Active Delay

The amount of time required for the input to be open or closed before indicating that the digital input is active. This feature can be used to debounce the input.

 

Digital Input 14 > Reaction

• Disabled (1/3)

The input will be ignored. Use this option if the input will not be used.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Digital Input 14 > Start Delay

The amount of time the controller will wait for the main pump to be running before ever looking for an alarm/shutdown condition on the digital input.  Once the start delay time is complete it will not be used again until the next system start.

 

Digital Input 14 > Detection Delay

After the start delay is complete, the controller will then use the detection delay.  If an alarm/shutdown condition is present for the amount of time in this setting, the controller will set an alarm or shutdown event depending on the setting of Reaction.

 

Digital Input 14 > Restart Type

• Manual (1/2)

If a shutdown event occurs, a manual restart will require an operator to either locally or remotely, via SCADA, reset the shutdown event before the system will restart.

 

• Timed (2/2)

If a shutdown event occurs, a timed restart will automatically reset the shutdown event after the time set in Restart Delay.

Digital Input 14 > Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

(DI15) TC Oil Flow

Configuration parameters related to Digital Input 15 are available in:

Configure > Digital Ins > Digital Input 15

 

Digital Input 15 does not have a dedicated function, but is configured to indicate low thrust chamber oil flow by default. The name can be modified by the operator.

 

Digital Input 15 > Active When

Determines when the digital input is considered to be active.

• Contact Open (1/2)

The digital input indication will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input indication will be active when the contact to the input is closed.

 

Digital Input 15 > Active Delay

The amount of time required for the input to be open or closed before indicating that the digital input is active. This feature can be used to debounce the input.

 

Digital Input 15 > Reaction

• Disabled (1/3)

The input will be ignored. Use this option if the input will not be used.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Digital Input 15 > Start Delay

The amount of time the controller will wait for the main pump to be running before ever looking for an alarm/shutdown condition on the digital input.  Once the start delay time is complete it will not be used again until the next system start.

 

Digital Input 15 > Detection Delay

After the start delay is complete, the controller will then use the detection delay.  If an alarm/shutdown condition is present for the amount of time in this setting, the controller will set an alarm or shutdown event depending on the setting of Reaction.

 

Digital Input 15 > Restart Type

• Manual (1/2)

If a shutdown event occurs, a manual restart will require an operator to either locally or remotely, via SCADA, reset the shutdown event before the system will restart.

 

• Timed (2/2)

If a shutdown event occurs, a timed restart will automatically reset the shutdown event after the time set in Restart Delay.

Digital Input 15 > Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

(DI16) Multipurpose

Configuration parameters related to Digital Input 16 are available in:

Configure > Digital Ins > Digital Input 16

 

Digital Input 16 is a multipurpose digital input that can be used for annunciation, alarm indication, shutdown event triggering, or remote resetting of shutdown or fault events. The name can be modified by the operator.

 

 

Digital Input 16 > Function

While most of the digital inputs have either a dedicated purpose or are general purpose, the function of Digital Input 16 is configurable by the operator.

• General Purpose (1/2)

The digital input will operate similar to one of the other digital inputs without a dedicated function. The configured Reaction determines what will occur when the input becomes active.

 

• Reset (2/2)

If a shutdown or fault event is currently set, the input will reset the shutdown or fault when the input is active.

 

Digital Input 16 > Active When

Determines when the digital input is considered to be active.

• Contact Open (1/2)

The digital input indication will be active when the contact to the input is open.

 

• Contact Closed (2/2)

The digital input indication will be active when the contact to the input is closed.

 

Digital Input 16 > Active Delay

The amount of time required for the input to be open or closed before indicating that the digital input is active. This feature can be used to debounce the input.

 

Digital Input 16 > Reaction

Generally, the Reaction should be set to Disabled when Function is configured for Reset.

• Disabled (1/3)

The input will be ignored. Use this option if the input will not be used.

 

• Alarm (2/3)

An alarm event will be indicated, but the system will continue to run.

 

• Shutdown (3/3)

A shutdown event will be triggered, and the system will stop after following the Post-Run sequence.

 

Digital Input 16 > Start Delay

The amount of time the controller will wait for the main pump to be running before ever looking for an alarm/shutdown condition on the digital input.  Once the start delay time is complete it will not be used again until the next system start.

 

Digital Input 16 > Detection Delay

After the start delay is complete, the controller will then use the detection delay.  If an alarm/shutdown condition is present for the amount of time in this setting, the controller will set an alarm or shutdown event depending on the setting of Reaction.

 

Digital Input 16 > Restart Type

• Manual (1/2)

If a shutdown event occurs, a manual restart will require an operator to either locally or remotely, via SCADA, reset the shutdown event before the system will restart.

 

• Timed (2/2)

If a shutdown event occurs, a timed restart will automatically reset the shutdown event after the time set in Restart Delay.

 

Digital Input 16 > Restart Delay

When a shutdown event occurs, and is configured for a timed restart, the shutdown event will automatically reset after this delay has expired.

 

 

Analog Outputs

Analog outputs available to the operator include:

• 1 4-20 mA
• 2 4-20 mA

 

The analog outputs are connected to one of the controller I/O modules. I/O module wiring is indicated for each individual output on subsequent pages.

Configuration parameters related to the Analog Outputs are available in:

Configure > Analog Outs

 

 

(AO1) Pressure Control Valve Position

Configuration parameters related to Analog Output 1 are available in:

Configure > Analog Outs > (AO1) Pressure Control Valve Position

 

The function of Analog Output 1 is dedicated to the pressure control valve position command, and is responsible for moving the pressure control valve to the desired position.

The 4-20ma signal is connected to terminals I and COM of group AO0 on the I/O module labeled IO-AI4-AO2.

 

 

(AO1) Pressure Control Valve Position > Function

The Function for (AO1) Pressure Control Valve Position is dedicated, and cannot be changed by the operator.

 

(AO1) Pressure Control Valve Position > Full Open (100%)

Depending on the brand and model of pressure control valve used, the signal value used to command the valve to the full open position may differ from installation to installation. Select the value that matches the signal value required by the valve to reach the full open position.

• 4 mA (1/2)

The pressure control valve is in the full open position when sending a 4 mA command signal.

 

• 20 mA (2/2)

The pressure control valve is in the full open position when sending a 20 mA command signal.

 

 

(AO2) Multipurpose

Configuration parameters related to Analog Output 2 are available in:

Configure > Analog Outs > (AO2) Multipurpose

 

The function of Analog Output 2 is dedicated to the pressure control valve position command, and is responsible for moving the pressure control valve to the desired position.

The 4-20ma signal is connected to terminals I and COM of group AO1 on the I/O module labeled IO-AI4-AO2.

 

(AO2) Pressure Control Valve Position > Function

The function of the (AO2) Multipurpose output is configurable by the operator.

• Block Valve Position (1/2)

The analog output will be used to command the position of an optional block valve.

 

• Retransmit Analog Input (2/2)

The analog output will retransmit one of the connected analog inputs selected by the operator.

 

(AO2) Pressure Control Valve Position > BV Full Open (100%)

When an optional block valve is installed, the block valve may require positioning commands via a 4-20 mA signal, rather than digital output contact closures. Depending on the make and model of the block valve control module used, the signal value used to command the valve to the full open position may differ from site to site. Select the value that matches the signal value required by the block valve control module to reach the full open position.

BV Full Open (100%) is disabled when Function is set to Retransmit Analog Input.

• 4 mA (1/2)

The block valve is in the full open position when sending a 4 mA command signal.

 

• 20 mA (2/2)

The block valve is in the full open position when sending a 20 mA command signal.

 

 

(AO2) Pressure Control Valve Position > Retransmit Analog Input

Occasionally, some installations may require simultaneously connecting a sensor to equipment other than just the OptiPump HPS controller. In this case, the OptiPump HPS controller can retransmit any one of the analog inputs connected via Analog Output 2.

When a temperature input is selected to retransmit, the OptiPump HPS controller will automatically scale the J-type thermocouple or RTD signal as: 4 mA = -100 °F and 20 mA = +500 °F.

Retransmit Analog Input is disabled when Function is set to Block Valve Position.

• Analog Input 1 (1/23)
• Analog Input 2 (2/23)
• Analog Input 3 (3/23)
• Analog Input 4 (4/23)
• Analog Input 5 (5/23)
• Analog Input 6 (6/23)
• Analog Input 7 (7/23)
• Analog Input 8 (8/23)
• Analog Input 9 (9/23)
• Analog Input 10 (10/23)
• Analog Input 11 (11/23)
• Analog Input 12 (12/23)
• Analog Input 13 (13/23)
• Analog Input 14 (14/23)
• Analog Input 15 (15/23)
• Analog Input 16 (16/23)
• Analog Input 17 (17/23)
• Analog Input 18 (18/23)
• Analog Input 19 (19/23)
• Analog Input 20 (20/23)
• Analog Input 21 (21/23)
• Analog Input 22 (22/23)
• Analog Input 23 (23/23)

 

Maintenance Reminders

Configuration parameters related to the Maintenance Reminder system are available in:

Configure > Maintenance

 

The OptiPump HPS controller includes a built-in Maintenance Reminder system that can automatically remind operators of the need to perform maintenance and other tasks at set intervals. 10 customizable Maintenance Reminders are available, each with independent reminder conditions.

 

 

Frequency

Frequency defines how often the reminder to should be activated.

• Disabled

The reminder will not be used.

 

• Run-Time

The reminder will activate based on the run-time hours of the device selected by Run-Time Source.

 

• Monthly

The reminder will activate monthly, based on the day of the month entered in the Day of Month parameter.

Run-Time Source

When Frequency is configured for Run-Time, the reminder will be activated based on the run-time hours of one of the following devices:

• Panel

The panel run-time hours track any time the panel is powered on, regardless of whether or not the main pump is running.

 

• Main Pump

The main pump run-time hours track the time the main pump is running.

 

• Charge Pump

The charge pump run-time hours track the time the charge pump is running.

 

• Thrst Chmbr Oil Pump

The thrust chamber oil pump run-time hours track the time the thrust chamber oil pump is running.

 

Name

A 20 character alphanumeric reminder name can be set by the operator for each of the 10 Maintenance Reminders. Since proper equipment maintenance is critical to the warranty and longevity of the equipment, the name should be chosen to provide facility personnel with a clear understanding of the maintenance task that needs to be performed.

 

Run-Time Hours

The Run-Time Hours are the number of hours of the selected Run-Time Source device at which the reminder should activate.

Run-Time Hours is disabled when Frequency is set to Disabled or Monthly.

Note:
If the maintenance task has been performed prior to the reminder activating, the Reminder Countdown hours can be reset immediately by holding down the Reset Countdown button for 5 seconds. When the Reset Countdown button is pressed, a 5 second countdown timer will appear. When the Hold status changes to Done, the reset is complete.

Monitors

Day of Month

When Frequency is configured for Monthly reminders, the reminder will activate every month on the Day of Month entered by the operator.

Day of Month is disabled when Frequency is set to Disabled or Run-Time.

 

System

Configuration parameters related to the System are available in:

Configure > System

 

System configuration parameters contain settings related to the overall performance of the controller, which includes items such as the date and time, SD card data logging, and device communication.

 

 

General

General system configuration parameters are available in:

Configure > System > General

 

General > Site Name

A 20 character alphanumeric site name can be set by the operator to uniquely identify an installation. The site name will be displayed at the top of all screens, as well as in the SD card data log.

 

General > RTC Date

The real-time clock (RTC) date. The RTC date is used to timestamp events and data samples in the log.

General > RTC Time

The real-time clock (RTC) time in 24-hour format. The RTC time is used to timestamp events and data samples in the log.

 

General > Screensaver

• Disabled (1/3)

The screen will always remain on. The display will return to the Home screen after 30 minutes of operator inactivity (touchscreen is not pressed).

 

• Blank (2/3)

After the period of operator inactivity (touchscreen is not pressed) specified in Screensaver Timeout, the display will return to the Home screen and turn off the screen backlight. Pressing anywhere on the touchscreen will "wake" the display.

 

• Pictures (3/3)

After the period of operator inactivity (touchscreen is not pressed) specified in Screensaver Timeout, the display will begin cycling through a series of product and application pictures. Pressing anywhere on the touchscreen will return the display to the Home screen.

 

General > Screensaver Timeout

The period of operator inactivity (touchscreen is not pressed) required before the screensaver activates. This value only applies when Screensaver is enabled.

 

General - Unlock Advanced Parameters > Analog Inputs

This feature is currently disabled and unavailable.

 

General - Unlock Advanced Parameters > Digital Inputs

This feature is currently disabled and unavailable.

 

General - Access Control > Operator Password

The 4-digit numeric password required to log-in as the Limited Operator access level. Refer to the Operator Access Level – Log In/Out section for more information.

 

General - Access Control > Supervisor Password

The 4-digit numeric password required to log-in as the Full Supervisor access level. Refer to the Operator Access Level – Log In/Out section for more information.

 

 

SD Card

SD Card system configuration parameters are available in:

Configure > System > General

 

The OptiPump HPS controller supports a standard microSD card, which can be used for periodic data logging, saving/loading configuration parameter values, and upgrading the controller firmware. The microSD card MUST be specially formatted in order for the controller to properly recognize and use the microSD card. Refer to the SD Card Formatting section for more detailed information on this process.

Note:
The HOA switch should be in the Off position before saving or loading configuration parameters to/from the microSD card or upgrading the controller firmware.

 

 

Data Logging

The data logging system records numerous samples in multiple comma-separated value (CSV) files on the microSD card. Each data sample within the log is a snapshot of the operational conditions present at that time. The CSV files are located on the microSD card in the following folders:

• EXCEL\EXCEL1
• EXCEL\EXCEL2
• EXCEL\EXCEL3
• EXCEL\EXCEL4

 

Each EXCEL folder can contain up to 64 CSV files, and each CSV file can contain up to 30,000 data samples. The CSV files are numerically named 1 through 64, in the order the files are created. When an EXCEL folder has reached the 64 file limit, the next EXCEL folder in the rotation is used, and the filename starts back at 1. This scheme allows for continuous data logging by overwriting the oldest log when no unused log files exist.

In order reduce the chances of data corruption, the data logging system should be stopped prior to removing the microSD card from the controller. If the logging status is currently active, simply press the Stop Logging button to suspend data logging, or power down the controller, before removing the microSD card.

 

Save/Load Parameters

The current configuration parameter values can be saved in a file on the microSD card for safe keeping (as a backup) or for reuse at other installation sites of similar configuration. The file format is a binary data file, and can only be read by the controller. The file is saved in the USER_APP folder on the microSD card, with a .D10 file extension.

To save the current configuration parameters to the microSD card, set the desired filename, without the .D10 file extension, in the Save Params Filename parameter, then press the green Save button immediately below the filename parameter. The controller will pause momentarily while the values are saved to the microSD card.

 

To load configuration parameter values from a .D10 file on the microSD card, press the green Load button. The file browser will open and display a list of .D10 files present in the USER_APP folder on the microSD card. Select the desired saved settings file by pressing on the filename in the list, then press the Send File button.
.

The controller will pause momentarily while the values are loaded from the microSD card.

 

SD Card > SD Card Status

A display-only (monitor) value that provides the current status of the microSD card.

SD Card > Logging Status

A display-only (monitor) value that provides the current status of the data logging system that writes samples to the microSD card.

 

SD Card - Logging > Log When

In order to provide flexibility for how data samples are recorded to the log, the data logging system can be configured to continuously record data samples, even when the system is not running, or only when the system is actively running.

• Always (1/2)

The data logging system records data samples continuously, even when the pump system is stopped. This option can be helpful when sensor data needs to be recorded prior to the pump system entering the run state. Because data samples are logged even when stopped, this option can fill the log with long periods of little data if the pump system is off for long periods.

 

• Running Only (2/2)

The data logging system records data samples ONLY when the system is actively running. This option can be helpful when the pump system is stopped or off for long periods of time, and can extend the total time recorded in the data log before overwrites occur.

 

SD Card - Logging > Logging Interval

The logging interval specifies the time between data samples in the log. Data samples can be recorded as fast a once every 1 second, or as slowly as once every 1 hour. Because the size of the log is limited by the number of data samples, the overall length of time the log will record can be extended by increasing the logging interval time. Short logging intervals can be used when troubleshooting quickly changing operational conditions.

 

SD Card - Save/Load Parameters & Upgrade Firmware > Save Params Filename

The filename of the configuration parameters that will be saved to the microSD card. This field applies ONLY when SAVING configuration parameters to the microSD card, and does NOT apply when LOADING configuration parameters.

 

SD Card - Save/Load Parameters & Upgrade Firmware > Upgrade

The OptiPump HPS controller supports field upgrades of the controller firmware. Controller firmware upgrades provide bug fixes and new features. However, technical support and/or engineering should be consulted prior to installing a firmware upgrade, in order to fully understand the changes between the firmware versions and the impact the changes may have on the operation of the equipment at the installation site.

The firmware upgrade file must be located in the SYSTEM folder on the microSD card, and end in the .C10 file extension.

Firmware upgrades may be installed using two methods:

• Method 1 - Configure > System > SD Card - Save/Load Parameters & Upgrade Firmware

 

Method 1, the recommended method, uses the standard configuration interface to install firmware upgrades, and is the most operator-friendly method of performing this function.

 

The upgrade file must exist in the SYSTEM folder on the microSD card. The upgrade file is often provided via email. The microSD card should be removed from the controller, and the supplied .C10 firmware upgrade file should be copied to the SYSTEM folder on the microSD card. Once the .C10 firmware upgrade file has been copied, the microSD card must be reinstalled in the controller.

 

The SD card status should indicate that the microSD card is present and OK.

 

Press the green Upgrade button to start the process.

 

A list of the firmware upgrade files in the SYSTEM folder will be displayed. Press the desired firmware upgrade file to be installed, then press the Send File button.

 

 

The controller will switch to the firmware upgrade mode while the process is ongoing, and will automatically reboot after the process completes.

 

The success or failure of the controller firmware upgrade process can be verified by checking the version of the firmware shown in the upper right corner of the Home screen with version displayed prior to the start of the firmware upgrade process.

 

• Method 2 - Info Mode

 

In the event that the controller firmware upgrade process does not correctly load using the standard configuration interface, a special mode, called Info Mode, may be used to upgrade the controller firmware outside of the standard configuration interface.

 

The upgrade file must exist in the SYSTEM folder on the microSD card. The upgrade file is often provided via email. The microSD card should be removed from the controller, and the supplied .C10 firmware upgrade file should be copied to the SYSTEM folder on the microSD card. Once the .C10 firmware upgrade file has been copied, the microSD card must be reinstalled in the controller.

 

While on the Configure > System > SD Card screen, press and hold the anywhere in the black background area below the SD Card - Save/Load Parameters & Upgrade Firmware section. After a few seconds, the Info Mode screen will appear. Press the Enter Info Mode button.

 

 

Enter the password "1111", and press Enter.

 

Press the SD button, then press the Full Clone button. When the Full Close button is pressed, the Upload to PLC button at the bottom of the screen will become active. Press the Upload to PLC button.

 

A list of the firmware upgrade files in the SYSTEM folder will be displayed. Press the desired firmware upgrade file to be installed, then press the Send File button. The controller will request confirmation of the firmware upgrade process. Press the Yes button to initiate the transfer process.

 

 

The controller will switch to the firmware upgrade mode while the process is ongoing, and will automatically reboot after the process completes.

 

The success or failure of the controller firmware upgrade process can be verified by checking the version of the firmware shown in the upper right corner of the Home screen with version displayed prior to the start of the firmware upgrade process.

 

Device Communication

Device communication configuration parameters are available in:

Configure > System > Device Communication

 

The OptiPump HPS controller supports two external device communication ports. The Ethernet port provides communication with both the variable frequency drive and with SCADA devices. One serial port is dedicated to communication with SCADA devices.

Note:
The controller must be rebooted or power-cycled in order for the changes made to the communication configuration parameters to take effect.

 

Communication ports available:

• Port 1

Configurable serial communication with the controller as a Modbus RTU slave device.

 

• Port 2

Disabled.

 

• Port 3

Configurable Ethernet communication with the variable frequency drive and SCADA devices as a Modbus TCP/IP slave device. For SCADA communication, the Modbus TCP/IP port is set to 502, and cannot be changed.

 

For serial communication ports, the hardware must be physically configured using DIP switches that must also match the associated configuration parameter. The hardware DIP switches are located on the back of the controller, and are configured using the table below.

 

 

The serial communication ports use a standard RJ-11 socket. The pinout for the sockets is shown below. Note that the pinout is different depending on the port type configured.

 

 

 

Device Communication - Serial Port 1 - SCADA > Port Type

The serial port for SCADA communication can be configured for either RS-232 or RS-485 communication. The serial port type must match the port type used by the SCADA monitoring device.

 

Device Communication - Serial Port 1 - SCADA > Baud Rate

The baud rate for the serial SCADA communication port should be configured to match the baud rate of the SCADA monitoring device.

 

Device Communication - Serial Port 1 - SCADA > Slave Address

The serial port SCADA slave address specifies the address of the controller on the serial Modbus RTU network. The slave address must be unique for all devices on the serial Modbus RTU network when multiple slave devices share the serial communication bus.

 

Device Communication - Serial Port 2 - VFD > Baud Rate

Feature disabled.

 

Device Communication - Serial Port 2 - VFD > Slave Address

Feature disabled.

 

Device Communication - Serial Port 2 - VFD > Ignore Communication Faults

Feature disabled.

 

Device Communication - Ethernet > IP Address

The IP address assigned to the controller. This address must be set by the operator. DHCP is NOT supported.

 

Device Communication - Ethernet > Subnet Mask

The subnet mask used by the controller. The subnet mask must be set by the operator. DHCP is NOT supported.

Device Communication - Ethernet > Default Gateway

The default gateway used by the controller. Setting the default gateway is optional, depending on the network. DHCP is not supported.

SCADA/Modbus Register Map

 

Monitors (16-Bit Holding Registers) - Read-Only (0x03)

 

 

Monitors (32-Bit Holding Registers) – Read-Only (0x03)

 

 

Monitors (Bits/Coils) – Read-Only (0x01)

 

 

Alarm Codes (Register 143)

 

 

Shutdown Codes (Register 144)

 

 

Fault Codes (Register 145)

 

 

VFD Fault Codes (Register 146)

 

 

Parameters (16-Bit Holding Registers) – Read/Write

 

 

Parameters (32-Bit Holding Registers) – Read/Write

 

Parameters (Bits/Coils) – Read/Write

Parameters (32-Bit Floating Point Holding Registers) – Read/Write

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