FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL VERSION 2.1x

S90-555 M/OCT 2001 File: SERVICE MANUAL - SECTION 90 Replaces: NOTHING (New Manual) Dist: 3, 3a, 3b, 3c FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL VERSION 2.1x

S90-555 M Page 2 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Table of Contents Quantum Identification 4 Quantum 3 4 Quantum 4 4 Troubleshooting 4 The Quantum Control Panel 4 General Information 4 What To Do Before Calling The Factory 5 What Should Occur When Powering Up The Panel 5 What If The Home Screen Is Not Shown 5 Troubleshooting GCU Board Analog And Digital Problems 7 About Screen 7 Diagnosing A GCU Board Problem 7 Troubleshooting Digital Inputs And Outputs 8 Troubleshooting Analog Inputs And Outputs 9 Adding And Replacing Boards 9 Quantum 9 GCU Boards 9 Display Replacement 10 Troubleshooting A Problem That Appears Unexplainable 10 Jumper And Dipswitch Settings 11 Digital Board (Optional) 11 Digital I/O Board Communications Settings 11 Digital I/O Board Dipswitch Settings (DP1) 11 Condenser / Vessel (GCU) Board: 12 Communications Port Connections 12 Additional Communications Jumper Configurations 12 GCU Board Dipswitch Settings 12 Vessel GCU Board Analog I/O Jumper Settings 13 Analog Output Configurations 14 Condenser GCU Board Analog I/O Jumper Settings 14 Analog Output Configurations 16 Quantum 3 Main Processor Board 17 Motherboard Jumpers 17 Communications Board Jumpers 18 Com-1 18 Com-2 18 Com-3 18 Communications Wiring 18 Quantum 4 Main Processor Board 19 Motherboard Jumpers 19 Communications Board Jumpers 20 Com-1 20 Com-2 20 Communications Wiring 20 Drawing Reference Table 21 Quantum Panel DC Power Supply Diagram (Condor) 22 Quantum Panel DC Power Supply Diagram (Power-One) 22 Quantum Control Center Assembly 23 Vessel Control Center Assembly 285 Wiring Diagram Vessel W/O MOA 31 Wiring Diagram Vessel With MOA 37 Condenser Control Center Assembly 43 Wiring Diagram Condenser 53 Quantum 3 Communications Wiring Diagrams 59

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 3 Rs-485 Communications 59 Rs-422 Communications 59 Rs-232 Communications 59 Quantum 4 Communications Wiring Diagrams 60 Rs-485 Communications 60 Rs-422 Communications 60 Rs-232 Communications 60 Convenser/Vessel Recommended Spare Parts 61 Quantum Control Panel 61 Remote Panel 61 Display Assembly Component Replacement Guide 61 QUANTUM PUBLICATIONS S90-555 CS Frick Quantum Condenser/Vessel Control Panel COMMUNICATIONS SETUP (setup and wiring for data communication using available protocols) S90-555 O Frick Quantum Condenser/Vessel Control Panel OPERATION E90-555 SD Frick Quantum Condenser/Vessel Control Panel SETPOINT DATA SHEETS Indicates an imminently! DANGER hazardous situation which, if not avoided, will result in death or serious injury.! WARNING Indicates a potentially hazardous situation or practice which, if not avoided, will result in death or serious injury.! CAUTION Indicates a potentially hazardous situation or practice which, if not avoided, will result in damage to equipment and/or minor injury. NOTE: Indicates an operating procedure, practice, etc., or portion thereof which is essential to highlight.

S90-555 M Page 4 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Quantum Identification Frick Controls has over the years, strived to remain on the cutting edge of microprocessor technology and development. And because of the ever-increasing speed, memory, features, and power of microprocessors, Frick Controls will, from time to time, introduce the latest advancement in microprocessor control technology. Our microprocessor family has shared the name Quantum over the past five years. There are currently four controllers within this family. The first two of these controllers (known as Quantum 1 and Quantum 2) are no longer in production, and as such, will not be further mentioned in this manual. The two current members in production of the Quantum family are the Quantum 3, and the Quantum 4. It is critical to the end user to be able to identify the differences between these controllers. Throughout this manual, the two different controllers will be talked about for the most part as one (as they do function the same). Where there is a difference between these boards, as in jumpers or wiring, the different models will be identified by name. This is why it is important for you to be aware of which board you have. Quantum 3 Quantum 4 TROUBLESHOOTING THE QUANTUM CONTROL PANEL This section contains information on troubleshooting and making corrections to the boards and control circuits of the Quantum. Reference the drawings at the end of this manual. GENERAL INFORMATION: The components within the control panel can be inadvertently damaged by static electricity or mishandling. Only qualified technicians should directly handle these components. 1. DO NOT attempt to make corrections to the power supply without shutting off power to the control panel. Accidental shorts can irreparably damage the processor boards or the display screen. 2. DO NOT HANDLE the panel boards when their cables are disconnected without first attaching a properly grounded wrist ground strap to prevent static electrical discharge from your body. Most problems encountered with the microprocessor and control circuits will be the result of a wiring fault, a blown fuse, faulty I/O module or failure of a peripheral control such as a solenoid coil or a pressure transducer. Faults in the computer, while possible, are unlikely. If a fault develops in the computer, the probability is that all functions will cease and the display screen will go blank. The control system consists of an AC (high voltage) side, which can be either 120 volts, or 230 volts, and a DC (low voltage) side. The AC side actuates solenoids, relays, alarms, and other electromechanical functions. The DC side operates the computer and it's various sensors. When working within the panel, the AC high voltage side, which can be either nominal 120 VAC or nominal 230 VAC, CAN CAUSE INJURY OR DEATH. To troubleshoot the low-voltage side of the control circuits, it is necessary to have the following tools: 1. Accurate digital multimeter* 2. Small wire stripper 3. Small screwdriver 4. Small snip nose pliers 5. Wrist Grounding strap* 6. Static free grounded work surface Note: Proper panel voltage refers to the AC (high voltage) that has been supplied to the panel, which could be either nominal 120 VAC or nominal 230 VAC (Reference the Control Panel Power Specifications). Some problems that are encountered involve troubleshooting digital inputs and outputs. The Digital I/O (Input/Output) board has six connectors labeled P1 through P6. The input and output modules are wired into a DIO connector plug. Position 3 provides 120 VAC power and position 4 is neutral. The GCU Board has three digital inputs connectors, labeled J7, J9, and J10. Each of these connectors has 16 pins. J10 is utilized for AC inputs, and use odd pin numbers for 120 VAC signals, even pins for neutral. J9 and J10 are for AC outputs, and use even pins for 120 VAC hot, odd pins are for 120 VAC signals.

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 5 WHAT TO DO BEFORE CALLING THE FACTORY The Home screen is shown. When someone calls in to the factory with a Quantum related problem, many times there isn't enough information provided. An example of this is the statement that the Panel is not booting (the main processor board is not starting). Unfortunately, this description is usually vague and only means that there is nothing on the display. A blank screen could be the result of many different problems. Following is a list of possible reasons for no display: No power Loose or Faulty Display Cable or Inverter Cable Bad Display Bad Backlight Inverter Bad Backlight Fluorescent Tube Faulty CPU Board Wrong Combination of Display, Cable, Inverter, or Software Before calling the factory for assistance, review the following information and try to discover what the problem is, and resolve it. WHAT SHOULD OCCUR WHEN POWERING UP THE PANEL The first thing that should be checked when troubleshooting the Quantum is it s powering up sequence. When powering up the Quantum the following sequence of events are indicative of a properly working main processor board: Quantum 3 The LED s for +5V, +12V, and 12V will turn on solid. (Lower left corner of Main PCB) LED KB will begin to blink. (Left side of Main PCB) Several initialization screens will appear (these will look very similar to the way the screen of a desktop computer appears when it is booting. The last of the initialization screens is the System Configuration screen. The screen will go blank for several seconds. The Home screen is shown. After the Quantum has properly powered up, the following sequence of events is indicative of proper communication to the GCU board: The TX/RX LED s near the white connector will begin to blink. The GCU board TX/RX lights should be blinking. Each GCU board should have the power LED (next to the white connector) lighted and the Status LED (next to the blue DIP switch) should be blinking. Quantum 4 Green PWR (Power) LED will turn on solid (upper right corner of main PCB). Red FLASH LED will begin to intermittently during the Boot process. It will then go out once the Home screen appears. LED D8 (on the smaller board) will start to blink at the rate of about once per second. It will continue to blink after the Quantum has booted. Once the screen displays Loading, LED's D4, D5, D7 and D8 will be on solid. The Home screen will appear. After the Quantum has properly powered up, the following sequence of events is indicative of proper communication to the analog and digital boards: The TX/RX LED s near the white connector will begin to blink. The GCU board TX/RX lights should be blinking. Each GCU board should have the power LED (next to the white connector) lighted and the Status LED (next to the blue DIP switch) should be blinking. WHAT IF THE HOME SCREEN IS NOT SHOWN If the Home screen is not shown, check the following items: Quantum 3 1. If no LED s are lighted, then check power AC and DC. 2. Check if the lighting of the LED s is occurring as described in the What Should Occur When Powering Up The Panel section. If the powering up sequence continues to repeat without displaying the Home screen, then there is a booting problem. 3. Check if an error message is displayed when booting. Be sure to write down any error messages that appear. 4. Check that the software is OK: Is the correct software installed? Did you just install new software? If you need to clear the numerical setpoint and calibration areas of memory for any reason, clear the memory as described in the S90-555 FSI publication. NOTE: This information will be replaced by factory default values, so any setpoint and calibration data values that need to be customized must be reentered.

S90-555 M Page 6 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL 5. Check for bad connections. 6. Check the display. If the CPU board is booting but you have no display, check the following: When working with the display, be extremely cautious of the backlight inverter board. This board is mounted next to the display, and is used to generate high voltage to drive the displays fluorescent tube. Check the LCD backlight tube. Look very closely at the display to see if anything is visible in the dark screen. You will need good lighting and look for any ghost type image. If it appears that there is something on the screen but very dark, the problem maybe the LCD backlight tube. On the LG Philips, NEC and Sharp displays this tube is field replaceable. On the Samsung LCD display, it is not available and the display will have to be replaced. You must take the display apart to identify the display manufacturer. Verify that both the display cable and the inverter cable are firmly seated. It may be necessary to remove the video cable from the back of the LCD display and reseat it to be sure it is connected properly. Note: This is a small connector and caution should be observed so that it is not damaged due to excessive force. Check the backlight inverter connector (P4). When the Quantum board is mounted in the panel, this connector is located at the middle left of the board. The pins on the right side are odd numbered, with pin P(1) at the bottom - pin P(9) at the top. The pins on the left side are even numbered, with pin P(2) at the bottom - pin P(10) at the top. After the Quantum has booted, pin P(3) should measure +2.4Vdc, pins P(4) and P(5) are DC grounds, and pins P(6) and P(7) should measure +12Vdc. A bad inverter will also cause a dark display. Reference the Display Assembly Component Replacement Guide at the end of this manual, and check that the LCD, LCD cable, and software versions are matched correctly. Quantum 4 1. If no LED s are lighted, then check power AC and DC. 2. Check if the lighting of the LED s is occurring as de-scribed in the What Should Occur When Powering Up The Panel section. If the powering up sequence continues to repeat without displaying the Home screen, then there is a booting problem. 3. Check if an error message is displayed when booting. Be sure to write down any error messages that appear. 4. Check that the software is OK: Is the correct software installed? Did you just install new software? If you need to clear the numerical setpoint and calibration areas of memory for any reason, clear the memory as described in the S90-555 FSI publication. NOTE: This information will be replaced by factory default values, so any setpoint and calibration data values that need to be customized must be reentered. 5. Check for bad connections. 6. Check the display. If the CPU board is booting but you have no display, check the following: When working with the display, be extremely cautious of the backlight inverter board. This board is mounted next to the display, and is used to generate high voltage to drive the displays fluorescent tube. Check the LCD backlight tube. Look very closely at the display to see if anything is visible in the dark screen. You will need good lighting and look for any ghost type image. If it appears that there is something on the screen but very dark, the problem maybe the LCD backlight tube. On the LG Philips, NEC and Sharp displays this tube is field replaceable. On the Samsung LCD display, it is not available and the display will have to be replaced. You must take the display apart to identify the display manufacturer. Verify that both the display cable and the inverter cable are firmly seated. It may be necessary to remove the video cable from the back of the LCD display and reseat it to be sure it is connected properly. Note: This is a small connector and caution should be observed so that it is not damaged due to excessive force. Reference the Display Assembly Component Replacement Guide at the end of this manual, and check that the LCD, LCD cable, and software versions are matched correctly.

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 7 TROUBLESHOOTING GCU BOARD ANALOG AND DIGITAL PROBLEMS The information that follows in this section can help locate problems that can occur with GCU Analog and Digital input and output circuit boards. About Screen The About screen shows any Condenser and Vessel GCU board(s) that have been detected. If a board has lost communications, the affected boards will continue to run their internal programs. Diagnosing a GCU Board Problem The GCU Board (both Condenser and Vessel) have builtin features that help to troubleshoot faulty boards. Following is a description of the built-in features: 1. The GCU Board has a Status LED indicator on the board that blinks when the board s software is running. If the Status LED is not blinking, check to ensure that the EPROM is installed properly. 2. There are also 5 volt and 12 volt power LED's that light when DC power is applied to the board. If the either power LED is not lighted, check the power harness for proper connectivity. If the harness appears to be good, then measure the voltages at the output of the DC power supply. 3. The main indication of communications is the RX/TX LED s on the GCU board. These LED s should blink in response to the blinking of the main processor board s I/O communication activity RX/TX LED s. If the RX LED on the GCU board is blinking but the board was not detected on the About screen, or an I/O Comm failure occurs, check the address of the board. Reference the JUMPER AND DIPSWITCH SETTINGS section later in this manual. This section contains the dipswitch settings for addressing all GCU Boards. When these switches are properly set, the main processor board is able to serially communicate with each board and provide data exchange.

S90-555 M Page 8 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Condenser Service - SCREEN - GCU Board Inputs and Outputs Vessel Service - SCREEN - GCU Board Inputs and Outputs Troubleshooting Digital Inputs and Outputs The Service Screen (individual service screens are available for both Condenser and Vessel) has been provided to view the raw data from a GCU Board. There is a separate screen for each of the GCU Boards that are present. Digital values are shown as ON or OFF. Checking the Digital Inputs and Outputs Some problems that are encountered involve troubleshooting the digital inputs and outputs. The Digital I/O (Input / Output) boards have three Digital I/O (DIO) board connectors labeled J7, J9 and J10. The input and output modules are wired to a connector plug: Input Module On the input module, positions 1, 3, 5, 7, 9, 11, 13, and 15 provides neutral on the DIO connectors. Positions 2, 4, 6, 8, 10, 12, 14, and 16 are signal connections. Input modules can only occupy the eight positions adjacent to connector J10. Output Module On the output module, positions 1, 3, 5, 7, 9, 11, 13, and 15 provides signal connections. Positions 2, 4, 6, 8, 10, 12, 14, and 16 are 120 volt AC on the DIO connectors. Output modules can only occupy the sixteen positions adjacent to connectors J7 and J9. Notice also, that these sixteen positions have fuses associated with them.

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 9 An LED is associated with each I/O module and displays the state of each module. A lighted LED represents an Input that is High or an Output that is On. If a properly configured GCU I/O is not responding correctly, first look at the board on the appropriate Service Screen (Condenser or Vessel) and check if the module is on. If it is not on, check if the LED on the board is also not lit. If the LED is not lit, then check the fuse. If the fuse is OK, then check the module. FUSE TESTING AND REPLACEMENT 1. Open the panel door. 2. Turn off circuit breaker 1CB. 3. Remove the questionable fuse. 4. Check the questionable fuse using a volt meter or other reliable method. If the fuse is faulty, replace the fuse with a new plug-type fuse (Part # 333Q0001326). 5. Turn on circuit breaker 1CB. Input and Output Module Testing and Replacement 1. Open the panel door. 2. Turn circuit breaker 1CB off. 3. Replace the questionable module. 4. Turn on circuit breaker 1CB. 5. If it is an output module, check for proper panel voltage on the DIO connector plug. Check the voltage between neutral the associated signal position to the output module. 6. If it is an input module, check if the associated LED is on when power is applied to the module. Troubleshooting an Output 1. Make sure the LED associated with the output is on when power is applied to the module. 2. If the LED is not on when it should be and there is no operating condition preventing it, contact the Frick Service Department. 3. If the LED is on when it should be, check for proper panel voltage on the DIO connector plug. Check the voltage between the neutral and the associated position to the output module. 4. If the voltage is OK, check for proper panel voltage between the associated position to the output module on the DIO connector and the associated position on the terminal strip. 5. If the voltage is OK, check the wiring external to the panel. 6. If voltage is not OK, check the fuse. 7. If the fuse is OK then check the module. 8. If the module is OK, check for proper panel voltage on the DIO connector plug between any odd numbered position (Hot) and neutral. Troubleshooting an Input 1. Ensure that the LED associated with the input is on when power is applied to the module. 2. If the LED is on, and there is good input voltage, then the module is good. 3. If the LED is on and there is no input voltage, replace the input module. Troubleshooting Analog Inputs and Outputs The Service Screen (both Condenser and Vessel) have been provided to view the raw analog data from a GCU Board. There is a separate screen for each of the GCU Boards that are present. Analog values are converted from binary to show volts. The error factor is.05 volts. Checking Analog Inputs and Outputs The GCU boards have numerous jumpers that must be properly selected. There are eleven analog input channels that can be selected for 4-20ma, Resistance, 0-5Vdc, or ICTD. All of these jumper settings are listed later in this manual (Jumper and Dipswitch Settings Section). Besides properly setting the hardware jumpers, each transducer must be calibrated through the appropriate sensor calibration screen. Improper setup of either the hardware or software will result in improper operation or range. The most common fault associated with the reading of the analog channels other than hardware or software setup problems fall into one of the following categories: Sensor fault, wiring problem, improper grounding of system. An open wire, shorted wire, or faulty sensor will usually give a reading at either the minimum, or maximum end of the range scale. An erratic reading or a reading that seems to float up and down is usually indicative of a grounding problem. When a single transducer or cable is shorted to earth (or system) ground, this can show up as a whole assortment of problem channels. The easiest way to find a short to earth problem is to disconnect all the sensor plugs and ohm out each plug screw terminal to earth for open (infinite) impedance. All sensors should read open to earth. ADDING AND REPLACING BOARDS QUANTUM The procedure to replace the main board is outlined below: 1. Shut off control power. 2. Remove the old board from the machine and the new board from its packing and place both on an anti-static surface. 3. Then install the modified replacement board in the panel. 4. Verify that all jumpers are installed properly. 5. Follow the directions in the Factory Setup manual (S90-555 FSI) for the procedure to load a program Flash Card. GCU BOARDS The procedure to replace a GCU board is outlined below: 1. Shut off control power. 2. Remove the old board from the enclosure and the new board from its packing and place both on an anti-static surface. 3. Remove any required chip(s) from the defective board and install them in the replacement board. Align the notch at the end of the EPROM with the notch in the socket. Ensure that the GCU EPROM (installed into U22), has the proper label affixed to it. If the GCU board being installed is to control a vessel, then the EPROM label must be printed with the words GCU VESSEL. Likewise, if the GCU board is being installed to control a condenser, then the EPROM label must be printed with the words "GCU

S90-555 M Page 10 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL CONDENSER". Additionally, the Version number should match between all GCU EPROMS, as well as the program version of the Quantum (as shown on the About screen). As an example, if the Quantum version is 2.11, then all GCU boards must have version 2.11. The GCU boards may have an additional digit in the version number, such as 2.112. This final digit is not critical with the compatibility of the system. 4. Ensure that all jumpers, dip switches, I/O modules and components are properly setup on the new board as it was on the old board. 5. Install the modified replacement board in the enclosure. After replacing a GCU board, it will automatically be detected after the Quantum power has been cycled off then on. It will then be necessary to re-enter all setpoints and calibration data to the board. Refer to the Factory Setup Instructions for more information (S90-555 FSI). DISPLAY REPLACEMENT 1. Shut off control power. 2. Remove the defective display. 3. Install the new display. TROUBLESHOOTING A PROBLEM THAT APPEARS UNEXPLAINABLE When there is a problem that makes no sense due to unexplainable things happening, then check the following: 1. It is important to know if the unit ever worked properly. 2. If the unit used to work properly, try to determine when the problem first showed up. 3. It is important to know if the problem occurs randomly, frequently, or all the time. 4. Check what the temperature is in the engine room and at the panel. Is it very hot or very cold? Make sure that the motor is not blowing exhaust air on the control panel. 5. If it just started to act up, then check if there was recently a severe lightning storm, fire, flood, or a plant accident. If any of the following conditions are possible, then check for it: Has any liquid leaked into the panel or conduit? 6. If it just started to act up, then check if anything was recently changed in the system (i.e. software or hardware.) 7. If it just started to act up, then check if any service was recently done to the electrical system? 8. If there is communication wiring connecting the panel to another panel or device, then check the following: If the Quantum is unexplainably shutting down, try disconnecting the communications cable to see if the problem goes away. Check if the communications cable shields are tied to machine ground at only one location. Check that you are using the Frick recommended communications cable. See manual to match proper cable with type of communications (i.e., RS-422, RS-232, RS- 485, or some other type of factory communication bus system.) 9. If this is an older plant, has the plant wiring been brought up to code? 10. Do you have power wiring mixed with control wiring? 11. Do you have power wiring mixed with sensor wiring? 12. Do you have power wiring mixed with communications wiring? 13. Check that the pressure transducers are properly grounded. The two types of transducers you may have are as follows: an older type has an 8 to 10 inch 3-conductor pigtail coming out of the transducer. This type will have the attaching cable s shield cut off and insulated at the transducer end. The shield is then tied to a panel ground terminal in the panel. The newer type has the cable as an integral part of the housing and has the shield crimped to the case at the transducer end. This type of transducer has the cable s shield cut off and insulated in the control panel. 14. Check that temperature transducers are properly grounded. Temperature probes usually have two short wires coming out of the sensor, and are tied to a shielded cable at the thermal well head. The shield is grounded at the temperature probe and insulated at the panel end. 15. Check if one of the temperature probes has a signal wire shorted to machine ground. To do this, first pull the orange plug from the micro board and then use an Ohmmeter and check each white wire to machine ground and each black wire to machine ground. 16. Ensure that all inductive loads (i.e. Coils, Solenoids, or Relays, etc.) connected to the I/O output modules have surge suppressers across them, preferably at the devices and not at the panel end. 17. If the control settings unexplainably change, it may be a noise problem affecting the keypad s input circuit. Check if it works OK with the keypad cable disconnected. If it works OK, then check the grounding as described above. If the grounding is OK, then replace the keypad. 18. Make sure that you have a continuous ground back to the power source. The ground connection must be aluminum or copper. A conduit ground will not work 19. Make sure that there is no AC wiring lying next to printed circuit boards. 20. Unexplainable auxiliary failures are usually indicative of noise due to wiring problems (i.e. incorrect earth grounds, mixed power and control wiring, unsuppressed coils, etc)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 11 JUMPER AND DIPSWITCH SETTINGS DIGITAL BOARD (Optional) DIGITAL I/O BOARD COMMUNICATIONS SETTINGS In J5 out* In J7 out* In J8 out* In J9 out* In J10 out* * = standard setting 120 ohm long communications line termination. No termination. (standard setting) RS-422/485 transmit pull-up for long communications lines. No pull-up. (standard setting) RS-422 transmit pull-up for long communications lines. No pull-up. (standard setting) RS-422/485 receive pull-down for long communications lines. No pull-down. (standard setting) RS-422 receive pull-down for long communications lines. No pull-down. (standard setting) DIGITAL I/O BOARD DIPSWITCH SETTINGS (DP1) SW1 SW2 SW3 SW4 SW5 SW6 Board #1 on on on on off on Board #2 off on on on off on Board #3 on off on on off on Board #4 off off on on off on Board #5 on on off on off on Board #6 off on off on off on

S90-555 M Page 12 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL PICTORIAL DRAWING OF CONDENSER / VESSEL (GCU) BOARD: Communications Port Connections Comm. Port 1 Comm. Port 2 Connector Function Connector Function J2-P2 Com- J3-P2 Com- J2-P3 Com+ J3-P3 Com+ Additional Communications Jumper Configurations Jumper Setting Function JP1 Installed Port 1 RS-485 pull-up resistor Removed No pull-up resistor (standard setting) JP2 Installed Port 1 RS-485 pull-down resistor Removed No pull-down resistor (standard setting) JP3 Installed Port 2 RS-485 pull-up resistor Removed No pull-up resistor (standard setting) JP4 Installed Port 2 RS-485 pull-down resistor Removed No pull-down resistor (standard setting) JP5 Installed PFI pull-up resistor (standard setting) Removed No pull-up resistor GCU Board Dipswitch Settings Switch # 1 Not Used N/A Switch # 2 Not Used N/A Switch # 3 Not Used N/A Switch # 4 Not Used N/A Switch # 5 Not Used N/A Switch # 6 Not Used N/A Switch # 7 Baud Rate Selection off / open * on / closed Switch # 8 Baud Rate Selection off / open on / closed * * = standard setting

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 13 Vessel GCU Board Analog I/O Jumper Settings Analog Input 1 - Vessel Level #1 Analog Input 1 Sensor Wiring Input Function JP8 JP9 Connector Function 0 5 VDC Out Out J4-10 +12 VDC Resistance 1-2 Out J4-11 Input Signal 4 20 ma * Out * 1 2 * J4-12 GND ICDT 2-3 Out Analog Input 2 - Vessel Level #2 Analog Input 2 Sensor Wiring Input Function JP18 JP19 Connector Function 0 5 VDC Removed Removed J4-7 +12 VDC Resistance 1-2 Removed J4-8 Input Signal 4 20 ma * Removed * 1 2 * J4-9 GND ICDT 2-3 Removed Analog Input 3 - Vessel Level #3 Analog Input 3 Sensor Wiring Input Function JP10 JP11 Connector Function 0 5 VDC Removed Removed J4-4 +12 VDC Resistance 1-2 Removed J4-5 Input Signal 4 20 ma * Removed * 1 2 * J4-6 GND ICDT 2-3 Removed Analog Input 4 - Vessel Pressure #1 Analog Input 4 Sensor Wiring Input Function JP20 JP21 Connector Function 0 5 VDC * Removed * Removed * J4-1 +12 VDC Resistance 1-2 Removed J4-2 Input Signal 4 20 ma Removed 1 2 J4-3 GND ICDT 2-3 Removed Analog Input 5 - Vessel Pressure #2 Analog Input 5 Sensor Wiring Input Function JP12 JP13 Connector Function 0 5 VDC * Removed * Removed * J5-10 +12 VDC Resistance 1-2 Removed J5-11 Input Signal 4 20 ma Removed 1 2 J5-12 GND ICDT 2-3 Removed Analog Input 6 - Vessel Pressure #3 Analog Input 6 Sensor Wiring Input Function JP22 JP23 Connector Function 0 5 VDC * Removed * Removed * J5-7 +12 VDC Resistance 1-2 Removed J5-8 Input Signal 4 20 ma Removed 1 2 J5-9 GND ICDT 2-3 Removed Analog Input 7 - Refrigeration Pump Pressure #1 Analog Input 7 Sensor Wiring Input Function JP14 JP15 Connector Function 0 5 VDC * Removed * Removed * J5-4 +12 VDC Resistance 1-2 Removed J5-5 Input Signal 4 20 ma Removed 1 2 J5-6 GND ICDT 2-3 Removed Analog Input 8 - Refrigeration Pump Pressure #2 Analog Input 8 Sensor Wiring Input Function JP24 JP25 Connector Function 0 5 VDC * Removed * Removed * J5-1 +12 VDC Resistance 1-2 Removed J5-2 Input Signal 4 20 ma Removed 1 2 J5-3 GND ICDT 2-3 Removed

S90-555 M Page 14 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Vessel GCU Board Analog I/O Jumper Settings (Continued) Analog Input 9 - Refrigeration Pump Pressure #3 Analog Input 9 Sensor Wiring Input Function JP16 JP17 Connector Function 0 5 VDC * Removed * Removed * J11-7 +12 VDC Resistance 1-2 Removed J11-8 Input Signal 4 20 ma Removed 1 2 J11-9 GND ICDT 2-3 Removed Analog Input 10 - Analog Auxiliary 1 Analog Input 10 Sensor Wiring Input Function JP26 JP27 Connector Function 0 5 VDC * Removed * Removed * J11-4 +12 VDC Resistance 1-2 Removed J11-5 Input Signal 4 20 ma Removed 1 2 J11-6 GND ICDT 2-3 Removed Analog Input 11 - Analog Auxiliary 1 Analog Input 11 Sensor Wiring Input Function JP6 JP7 Connector Function 0 5 VDC * Removed * Removed * J11-1 +12 VDC Resistance 1-2 Removed J11-2 Input Signal 4 20 ma Removed 1 2 J11-3 GND ICDT 2-3 Removed Analog Output Configurations Analog Output 1 Sensor Wiring - Vessel #1 Modulating Valve Analog Output 2 Sensor Wiring - Vessel #2 Modulating Valve Connector Function Connector Function J8-8 Output Signal J8-6 Output Signal J8-7 GND J8-5 GND Analog Output 3 Sensor Wiring - Vessel #3 Modulating Valve Analog Output 4 Sensor Wiring - Future Connector Function Connector Function J8-4 Output Signal J8-2 Output Signal J8-3 GND J8-1 GND Condenser GCU Board Analog I/O Jumper Settings

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 15 Analog Input 1 - Condenser Pressure Analog Input 1 Sensor Wiring Input Function JP8 JP9 Connector Function 0 5 VDC * Out * Out * J4-10 +12 VDC Resistance 1-2 Out J4-11 Input Signal 4 20 ma Out 1 2 J4-12 GND ICDT 2-3 Out Analog Input 2 - Outside Air Temperature Analog Input 2 Sensor Wiring Input Function JP18 JP19 Connector Function 0 5 VDC Removed Removed J4-7 +12 VDC Resistance 1-2 Removed J4-8 Input Signal 4 20 ma Removed 1 2 J4-9 GND ICDT * 2-3 * Removed * Analog Input 3 - Outside Air Humidity Analog Input 3 Sensor Wiring Input Function JP10 JP11 Connector Function 0 5 VDC Removed Removed J4-4 +12 VDC Resistance 1-2 Removed J4-5 Input Signal 4 20 ma * Removed * 1 2 * J4-6 GND ICDT 2-3 Removed Analog Input 4 - Condenser Drain Temp. (Refrigerant) Analog Input 4 Sensor Wiring Input Function JP20 JP21 Connector Function 0 5 VDC Removed Removed J4-1 +12 VDC Resistance 1-2 Removed J4-2 Input Signal 4 20 ma Removed 1 2 J4-3 GND ICDT * 2-3 * Removed * Analog Input 5 - Future Analog Input 5 Sensor Wiring Input Function JP12 JP13 Connector Function 0 5 VDC Removed Removed J5-10 +12 VDC Resistance 1-2 Removed J5-11 Input Signal 4 20 ma * Removed * 1 2 * J5-12 GND ICDT 2-3 Removed Analog Input 6 - Future Analog Input 6 Sensor Wiring Input Function JP22 JP23 Connector Function 0 5 VDC Removed Removed J5-7 +12 VDC Resistance 1-2 Removed J5-8 Input Signal 4 20 ma * Removed * 1 2 * J5-9 GND ICDT 2-3 Removed Analog Input 7 - Future Analog Input 7 Sensor Wiring Input Function JP14 JP15 Connector Function 0 5 VDC Removed Removed J5-4 +12 VDC Resistance 1-2 Removed J5-5 Input Signal 4 20 ma * Removed * 1 2 * J5-6 GND ICDT 2-3 Removed Analog Input 8 - Future Analog Input 8 Sensor Wiring Input Function JP24 JP25 Connector Function 0 5 VDC Removed Removed J5-1 +12 VDC Resistance 1-2 Removed J5-2 Input Signal 4 20 ma * Removed * 1 2 * J5-3 GND ICDT 2-3 Removed

S90-555 M Page 16 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Condenser GCU Board Analog I/O Jumper Settings (Continued) Analog Input 9 - Future Analog Input 9 Sensor Wiring Input Function JP16 JP17 Connector Function 0 5 VDC Removed Removed J11-7 +12 VDC Resistance 1-2 Removed J11-8 Input Signal 4 20 ma * Removed * 1 2 * J11-9 GND ICDT 2-3 Removed Analog Input 10 - Future Analog Input 10 Sensor Wiring Input Function JP26 JP27 Connector Function 0 5 VDC Removed Removed J11-4 +12 VDC Resistance 1-2 Removed J11-5 Input Signal 4 20 ma * Removed * 1 2 * J11-6 GND ICDT 2-3 Removed Analog Input 11 - Future Analog Input 11 Sensor Wiring Input Function JP6 JP7 Connector Function 0 5 VDC Removed Removed J11-1 +12 VDC Resistance 1-2 Removed J11-2 Input Signal 4 20 ma * Removed * 1 2 * J11-3 GND ICDT 2-3 Removed Analog Output Configurations Analog Output 1 Sensor Wiring - Variable Fan 1 Analog Output 2 Sensor Wiring - Variable Fan 2 Connector Function Connector Function J8-8 Output Signal J8-6 Output Signal J8-7 GND J8-5 GND Analog Output 3 Sensor Wiring - Variable Fan 3 Analog Output 4 Sensor Wiring - Variable Fan 4 Connector Function Connector Function J8-4 Output Signal J8-2 Output Signal J8-3 GND J8-1 GND

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 17 QUANTUM 3 MAIN PROCESSOR BOARD LK1-1 LK1-2 COM3 IRQ Routing (DO NOT MODIFY) A * A * RS-232 Interface Selected A B Not Valid Combination B A Not Valid Combination B B Touchscreen Controller Interface Selected LK2 A B * LK3 A B * LK4 In * Out COM3 IRQ Routing (DO NOT MODIFY) IRQ4 IRQ11 COM4 IRQ Routing (DO NOT MODIFY) IRQ3 IRQ10 RS-422 Termination (DO NOT MODIFY) RS-422 Terminated RS-422 Terminated LK5 RS-485 Receiver (DO NOT MODIFY) In RS-485 Receiver Enabled Out * RS-485 Receiver Disabled LK6 In * Out RS-485 Termination (DO NOT MODIFY) RS-485 Terminated RS-485 Not Terminated * Standard Setting Quantum 3 Motherboard Jumpers LK7 In Out * LK8 In Out * LK9 A B * LK10 A B * LK11 A * B Enabled Disabled Watchdog Timer Enable Watchdog timer Enable 2 second timeout 8 second timeout Clear CMOS/Battery Disable (DO NOT MODIFY) Battery Backup Enabled Battery Backup Disabled (CMOS RAM Cleared) LCD Backlight Voltage Supply Voltage +5V Backlight +12V Backlight LCD Panel Power Supply Voltage +5V Supply (Samsung, NEC or Sharp Displays) +3.3V Supply (LG Phillips Display) LK12 User Application Link (DO NOT MODIFY) In * Bit 1 of 259H "Logic 1" Out Bit 1 of 259H "Logic 0" LK13 User Application Link (DO NOT MODIFY) In * Bit 2 of 259H "Logic 1" Out Bit 2 of 259H "Logic 0"

S90-555 M Page 18 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Quantum 3 Communications Board Jumpers COM-1 (Jumpers located adjacent to connector TB1) In* Pull down Rx- / Tx- (RS485) or Rx- (RS422) line to GND (0V) via a 10K resistor. (standard setting) Link 1 out No pull down in Terminate Rx / Tx (RS485) or Rx (RS422) lines with a 120W resistor. (standard setting) Link 2 out* No termination (standard setting) in* Pull up Rx+ / Tx+ (RS485) or Rx+ (RS422) line to VCC (5V) via a 10K resistor. (standard setting) Link 3 out No termination. in* Pull down Tx- (RS422) line to GND (0V) via a 10K resistor. (standard setting) Link 4 out No pull down. in* Pull up COM2 Tx+ (RS422) line to VCC (5V) via a 10K resistor. (standard setting) Link 5 out No pull down. A* RS485 (standard setting) Link 16 B RS422 COM-2 (Jumpers located adjacent to connector TB2) In* Pull down Rx- / Tx- (RS485) or Rx- (RS422) line to GND (0V) via a 10K resistor. (standard setting) Link 6 out No pull down in Terminate Rx / Tx (RS485) or Rx (RS422) lines with a 120W resistor. (standard setting) Link 7 out* No termination (standard setting) in* Pull up Rx+ / Tx+ (RS485) or Rx+ (RS422) line to VCC (5V) via a 10K resistor. (standard setting) Link 8 out No termination. in* Pull down Tx- (RS422) line to GND (0V) via a 10K resistor. (standard setting) Link 9 out No pull down. in* Pull up COM2 Tx+ (RS422) line to VCC (5V) via a 10K resistor. (standard setting) Link 10 out No pull down. A* RS485 (standard setting) Link 17 B RS422 Link 19 in* Select RS422/RS485 comms mode. (standard setting) out Select RS232 comms mode. COM-3 (Jumpers located adjacent to connector TB3) Link 11 In* Pull down Rx- / Tx- (RS485) or Rx- (RS422) line to GND (0V) via a 10K resistor. (standard setting) out No pull down Link 12 in Terminate Rx / Tx (RS485) or Rx (RS422) lines with a 120W resistor. (standard setting) out* No termination (standard setting) Link 13 in* Pull up Rx+ / Tx+ (RS485) or Rx+ (RS422) line to VCC (5V) via a 10K resistor. (standard setting) out No termination. Link 14 in* Pull down Tx- (RS422) line to GND (0V) via a 10K resistor. (standard setting) out No pull down. Link 15 in* Pull up COM2 Tx+ (RS422) line to VCC (5V) via a 10K resistor. (standard setting) out No pull down. Link 18 A* RS485 (standard setting) B RS422 TB1 - COM1 RS-485/422 (Used for Sequencing): 4-way screw terminal Pin Signal (RS-422) Signal (RS-485) 4 COM1 TX+ - 3 COM1 TX- - 2 COM1 RX+ COM1 TX+ / RX+ 1 COM1 RX- COM1 TX- / RX- TB2 - COM2 RS-485/422 (Standard Communications): 4-way screw terminal Pin Signal (RS-422) Signal (RS-485) 4 COM2 TX+ - 3 COM2 TX- - 2 COM2 RX+ COM2 TX+ / RX+ 1 COM2 RX- COM2 TX- / RX- Quantum 3 Communications Wiring TB3- COM3 RS-485/422: 4-way screw terminal Pin Signal (RS-422) Signal (RS-485) 4 COM3 TX+ - 3 COM3 TX- - 2 COM3 RX+ COM3 TX+ / RX+ 1 COM3 RX- COM3 TX- / RX-

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 19 LCD Display & Inverter Cable (Plugs into PL15) PL5 PL15 LK3 LK4 A B PL11 QUANTUM 4 MAIN PROCESSOR BOARD Flash Card Socket (Located under board) COM-2 RS-232 This assembly is shipped with LK4 set to "B" position for an LG Phillips display (11.75" backplate). If using a Samsung, NEC or Sharp Display, set LK4 to position "A" (12.75" backplate). Keypad Cable plugs into PL1 TB3 PL1 PL3 PL3 PL4 COM-2 RS-422 RS-485 LK1 LK3 LK4 D8 B A LK17 A B LK2 LK5 LK6 LK7 LK8 D1 B A B A LK16 D2 LK11 D6 To set Comm-2 for RS-232 operation, set LK17 to "A" position. To set Comm-2 for RS-422/485 operation, set LK17 to "B" position. PL4 LK5 LK6 LK7 TB2 TB1 LK9 LK10 PL2 PL2 COM-1 RS-422 RS-485 D3 PORT 80H D4 D5 D7 D8 D10 D11 D12 D13 O 1 2 3 4 5 6 7 8 SW1 7 6 5 4 3 2 1 0 PL1 PL14 LK8LK10 LK9 PL16 LK11 PL6 PL10 FLASH PWR LK12 LK2 PL8 PL13 PL18 PL19 LK1 PL7 PL9 PL12 PL17 Power - I/O Comm. Harness (Plugs into PL12 & PL14) SUSP PL24 Bottom board is the Processor Board Top board is the Communications Board Quantum 4 Motherboard Jumpers LK1 Watchdog timer timeout selection In 2 second timeout Out * 8 second timeout LK7 Clear CMOS / Battery Disable (DO NOT MODIFY) A * Battery Backup Enabled B Battery Backup Disabled (CMOS RAM Cleared) LK2 In * Out Enabled Disabled Watchdog timer Enable LK8 In * Out RS-485 Receiver (DO NOT MODIFY) RS-485 Receiver Enabled RS-485 Receiver Disabled LK3 A B * Backlight Voltage +5V Backlight +12V Backlight LK9 In * Out RS-485 Termination (DO NOT MODIFY) RS-485 Terminated RS-485 Not Terminated LK4 A B * LCD Panel Power Supply Voltage +5V Supply (Samsung, NEC or Sharp Displays) +3.3V Supply (LG Phillips Display) LK10 In Out * RS-422 Termination (DO NOT MODIFY) RS-422 Terminated RS-422 Terminated LK5 A B * LK6 A B * COM4 IRQ Routing (DO NOT MODIFY) IRQ3 IRQ10 COM3 IRQ Routing (DO NOT MODIFY) IRQ4 IRQ11 LK11 User Application Link (DO NOT MODIFY) In * Bit 1 of 259H "Logic 1" Out Bit 1 of 259H "Logic 0" LK12 User Application Link (DO NOT MODIFY) In * Bit 2 of 259H "Logic 1" Out Bit 2 of 259H "Logic 0" * Standard Setting

S90-555 M Page 20 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL Quantum 4 Communications Board Jumpers Com-1 (TB1) In Terminate COM1 Rx / Tx (RS-485) or COM1 Rx (RS-422) lines with a 120W resistor. Link 2 out* No termination (standard setting) In* Pull down COM1 Rx- / Tx- (RS-485) or COM1 Rx- (RS-422) line to GND (0V) via a 10K res. (std. setting) Link 7 Out No pull down in* Pull up COM1 Rx+ / Tx+ (RS-485) or COM1 Rx+ (RS-422) line to VCC (5V) via a 10K res.. (std. setting) Link 8 out No termination. in* Pull down COM1 Tx- (RS-422) line to GND (0V) via a 10K resistor. (standard setting) Link 9 out No pull down. in* Pull up COM1 Tx+ (RS-422) line to VCC (5V) via a 10K resistor. (standard setting) Link 10 out No pull down. A* COM1 RS-485 (TB1) (standard setting) Link 16 B COM1 RS-422 (TB1) * = standard setting Com-2 (TB2 - TB3) In Terminate COM2 Rx / Tx (RS-485) or COM2 Rx (RS-422) lines with a 120W resistor. Link 1 out* No termination (standard setting) In* Pull down COM2 Rx- / Tx- (RS-485) or COM2 Rx- (RS-422) line to GND (0V) via a 10K res. (std. setting) Link 3 Out No pull down in* Pull up COM2 Rx+ / Tx+ (RS-485) or COM2 Rx+ (RS-422) line to VCC (5V) via a 10K res. (std. setting) Link 4 out No termination. in* Pull down COM2 Tx- (RS-422) line to GND (0V) via a 10K resistor. (standard setting) Link 5 out No pull down. in* Pull up COM2 Tx+ (RS-422) line to VCC (5V) via a 10K resistor. (standard setting) Link 6 out No pull down. A* COM2 RS-485 (TB2) (standard setting) Link 11 B COM2 RS-422 (TB2) A Select RS-232 comms mode for COM2 (TB3). Link 17 B* Select RS-422/RS-485 comms mode for COM2 (TB2). (standard setting) * = standard setting TB1 - COM1 RS-485/422 (Used for Sequencing): 4-way screw terminal Pin Signal (RS-422) Signal (RS-485) 4 COM1 TX+ - 3 COM1 TX- - 2 COM1 RX+ COM1 TX+ / RX+ 1 COM1 RX- COM1 TX- / RX- TB2 - COM2 RS-485/422 (Standard Communications): 4-way screw terminal Pin Signal (RS-422) Signal (RS-485) 4 COM2 TX+ - 3 COM2 TX- - 2 COM2 RX+ COM2 TX+ / RX+ 1 COM2 RX- COM2 TX- / RX- Quantum 4 Communications Wiring TB3- COM2 RS-232 (Standard Communications): 3-way screw terminal Pin Signal (RS-422) 3 Ground 2 RX 1 TX

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 21 DRAWING REFERENCE TABLE DRAWING NAME Quantum Panel DC Power Supply Diagram (Condor) Quantum Panel DC Power Supply Diagram (Power One) Quantum Control Center Assembly Vessel Control Center Assembly Wiring Diagram Vessel W/O MOA Wiring Diagram Vessel With MOA Condenser Control Center Assembly Wiring Diagram Condenser Quantum 3 Communications Wiring Diagrams Quantum 4 Communications Wiring Diagrams DRAWING NUMBER N/A N/A 649D4587 640D0160 640D0158 640D0159 640D0163 640D0161 N/A N/A The drawings that appear on the following pages are for reference purposes only, and are based upon the latest revision available at the time of this printing.

S90-555 M Page 22 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL QUANTUM PANEL DC POWER SUPPLY DIAGRAM (CONDOR) Replacement Part # 640C0022G01 7.25 F1 3.15 R51 +5V ADJ INPUT: J1 INPUT: J2 AMP P/N: 640445-5.312 CTR CONNECTOR, 3 CIRCUITS AMP P/N: 1-640445-3.156 CTR CONNECTOR, 13 CIRCUITS Pin 1 AC GROUND PIN 1 OUTPUT #1 Pin 3 AC NEUTRAL PIN 2 OUTPUT #1 PIN 5 AC LINE PIN 3 OUTPUT #1 PIN 4 COMMON OUTPUT 1 +5.1V PIN 5 COMMON OUTPUT 2 +24V PIN 6 COMMON OUTPUT 3-12V PIN 7 COMMON OUTPUT 4 12V PIN 8 OUTPUT #2 PIN 9 OUTPUT #2 MATING CONNECTORS: MOLEX PIN 10 POWER FAIL HOUSING CONTACT PIN 11 OUTPUT #3 INPUT 26-03-4050 08-52-0113 PIN 12 COMMON OUTPUT 26-03-4131 08-52-0113 PIN 13 OUTPUT #4 J1 5 1 13 4.50 J2 1 QUANTUM PANEL D.C. POWER SUPPLY DIAGRAM (POWER-ONE) Pin 3 TB1 Pin 1 3 1 TB1 GND Pin 1 NEUTRAL Replacement Part # 640C0022G11 HOT Pin 3 TB2 V4 (+12) Pin 1 V3 (-12V) V2 (+12V) V2 (+12V) ADJ V1 (+5V) ADJ GND GND V1 (+5V) 7 1 V1 (+5V) Pin 7 J1 Pin 7 TB2 Pin 1 GND J1 POWER FAILURE SIGNAL

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 23 QUANTUM CONTROL CENTER ASSEMBLY (SHEET 1 OF 2)

S90-555 M Page 24 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL QUANTUM CONTROL CENTER ASSEMBLY (SHEET 2 OF 2)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 25 VESSEL CONTROL CENTER ASSEMBLY (Sheet 1 of 6)

S90-555 M Page 26 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL VESSEL CONTROL CENTER ASSEMBLY (Sheet 2 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 27 VESSEL CONTROL CENTER ASSEMBLY (Sheet 3 of 6)

S90-555 M Page 28 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL VESSEL CONTROL CENTER ASSEMBLY (Sheet 4 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 29 VESSEL CONTROL CENTER ASSEMBLY (Sheet 5 of 6)

S90-555 M Page 30 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL VESSEL CONTROL CENTER ASSEMBLY (Sheet 6 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 31 WIRING DIAGRAM VESSEL W/O MOA (Sheet 1 of 6)

S90-555 M Page 32 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL WIRING DIAGRAM VESSEL W/O MOA (Sheet 2 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 33 WIRING DIAGRAM VESSEL W/O MOA (Sheet 3 of 6)

S90-555 M Page 34 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL WIRING DIAGRAM VESSEL W/O MOA (Sheet 4 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 35 WIRING DIAGRAM VESSEL W/O MOA (Sheet 5 of 6)

S90-555 M Page 36 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL WIRING DIAGRAM VESSEL W/O MOA (Sheet 6 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 37 WIRING DIAGRAM VESSEL WITH MOA (Sheet 1 of 6)

S90-555 M Page 38 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL WIRING DIAGRAM VESSEL WITH MOA (Sheet 2 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 39 WIRING DIAGRAM VESSEL WITH MOA (Sheet 3 of 6)

S90-555 M Page 40 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL WIRING DIAGRAM VESSEL WITH MOA (Sheet 4 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 41 WIRING DIAGRAM VESSEL WITH MOA (Sheet 5 of 6)

S90-555 M Page 42 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL WIRING DIAGRAM VESSEL WITH MOA (Sheet 6 of 6)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 43 CONDENSER CONTROL CENTER ASSEMBLY (Sheet 1 of 10)

S90-555 M Page 44 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL CONDENSER CONTROL CENTER ASSEMBLY (Sheet 2 of 10)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 45 CONDENSER CONTROL CENTER ASSEMBLY (Sheet 3 of 10)

S90-555 M Page 46 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL CONDENSER CONTROL CENTER ASSEMBLY (Sheet 4 of 10)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 47 CONDENSER CONTROL CENTER ASSEMBLY (Sheet 5 of 10)

S90-555 M Page 48 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL CONDENSER CONTROL CENTER ASSEMBLY (Sheet 6 of 10)

FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL S90-555 M Page 49 CONDENSER CONTROL CENTER ASSEMBLY (Sheet 7 of 10)

S90-555 M Page 50 FRICK QUANTUM CONDENSER/VESSEL CONTROL PANEL CONDENSER CONTROL CENTER ASSEMBLY (Sheet 8 of 10)