American Magnetics 05500PS-430-601 User Manual

EXCELLENCE IN MAGNETICS AND CRYOGENICS
MODEL 05500PS-430-601
HIGH STABILITY
INTEGRATED POWER
SUPPLY SYSTEM
INSTALLATION, OPERATION, AND
American Magnetics, Inc.
P.O. Box 2509, 112 Flint Road, Oak Ridge, TN 378 31 -25 09, Tel: 865-482-1056, Fax: 865-482-5472
Rev. 5; Issue: November 28, 2011
1 Table of Contents

Table of Contents

Table of Contents............................................................................... iii
List of Figures.................................................................................... ix
List of Tables...................................................................................... xi
Foreword........................................................................................... xiii
Introduction......................................................................................... 1
1.1 Model 05500PS-430-601 Integrated Power Supply System Features 1
Purpose and Scope .............................................................................xiii
Contents of this Manual .................................................................... xiii
General Precautions........................................................................... xiv
Safety Summary................................................................................. xvi
1.1.1 Digitally-Controlled................................................................... 1
1.1.2 Superior Resolution and Stability ............................................ 1
1.1.3 Intuitive Human-Interface Design........................................... 1
1.1.4 Flexibility................................................................................... 2
1.1.5 Standard Remote Interfaces..................................................... 2
1.1.6 Programmable Safety Features................................................ 2
1.1.7 Condition-Based Magnet Auto-Rampdown.............................. 2
1.1.8 Model 05500PS-430-601 General Description ......................... 3
1.1.9 Power Supply System Rack Front Panel Layout ................. 4
1.2 Model 430 Front Panel Layout............................................................. 5
1.3 Model 430 Rear Panel Layout ............................................................. 6
1.4 Power Supply Unit Front Panel Layout .............................................. 7
1.5 Model 601 Energy Absorber Front Panel Layout ............................... 8
1.6 System Specifications @ 25°C ............................................................ 9
1.7 Operating Characteristics ................................................................. 10
1.7.1 Dual-Quadrant Operation ...................................................... 10
Installation......................................................................................... 13
2.1 Inspecting and Unpacking.................................................................. 13
2.2 Power Supply System Mounting ........................................................ 13
2.3 Power Requirements........................................................................... 14
2.3.1 Changing the Model 430 Programmer Operating Voltage ... 14
2.4 Collecting Necessary Information...................................................... 15
2.5 System Interconnects.......................................................................... 15
2.5.1 High-Stability Bipolar Supply ................................................ 16
Rev. 5 iii
Table of Contents
2.6 Special Configurations.........................................................................20
2.7 Superconducting Magnets with No Persistent Switch ......................21
2.8 Short-Circuit or Resistive Load...........................................................21
2.9 Power-Up and Test Procedure ............................................................22
Operation............................................................................................27
3.1 System Power On/Off Sequence .........................................................27
3.1.1 Model 430 Programmer Power On/Off....................................27
3.1.2 Energizing Power Supply and Components ...........................28
3.2 Model 430 Programmer Default Display............................................29
3.2.1 Field / Current Display ............................................................29
3.2.2 Voltage Display ........................................................................30
3.2.3 Status Indicator .......................................................................31
3.2.4 Main Display ............................................................................31
3.3 Entering Numeric Values....................................................................31
3.4 Using Fine Adjust Knob to Adjust Numeric Values ..........................33
3.5 Entering Picklist Values......................................................................34
3.6 Single-key Commands / Menu.............................................................35
3.6.1 Persistent Switch Control Key ................................................35
3.6.2 Target Field Setpoint Key ......................................................37
3.6.3 Ramp / Pause Key ....................................................................38
3.6.4 Ramp To Zero Key....................................................................38
3.7 SHIFT-key Commands / Menus..........................................................39
3.7.1 Ramp Rate SHIFT-key ............................................................39
3.7.2 Voltage Limit SHIFT-key ........................................................43
3.7.3 Reset Quench SHIFT-key ........................................................43
3.7.4 Increment Field SHIFT-key ....................................................44
3.7.5 Field <> Current SHIFT-key...................................................44
3.7.6 Decrement Field SHIFT-key ...................................................44
3.7.7 Field Units SHIFT-key ............................................................45
3.7.8 Persistent Switch Heater Current SHIFT-key.......................45
3.7.9 Stability SHIFT-key.................................................................45
3.7.10 Vs <> Vm SHIFT-key...............................................................45
3.7.11 Volt Meter SHIFT-key .............................................................45
3.7.12 Fine Adjust SHIFT-key............................................................46
3.7.13 Persist. Switch Control SHIFT-key ........................................46
3.8 LED Indicators.....................................................................................46
3.8.1 Power-on Indicator...................................................................46
3.8.2 Magnet Status Indicators ........................................................46
3.8.3 SHIFT Indicator.......................................................................47
iv Rev. 5
Table of Contents
3.9 Setup Menu ......................................................................................... 47
3.9.1 Entering / Exiting Setup Menu .............................................. 48
3.9.2 Menu Navigation..................................................................... 48
3.10 Setup Submenu Descriptions ............................................................. 48
3.10.1 Supply Submenu ..................................................................... 49
3.10.2 Load Submenu......................................................................... 54
3.10.3 Misc Submenu ......................................................................... 65
3.10.4 Net Settings Submenu............................................................ 74
3.10.5 Net Setup Submenu ................................................................ 76
3.11 Example Setup .................................................................................... 78
3.12 Ramping Functions ............................................................................ 81
3.12.1 Ramping States and Controls ................................................ 81
3.12.2 Manual Ramping..................................................................... 82
3.12.3 Automatic Ramping ................................................................ 82
3.12.4 Ramping to Zero ...................................................................... 83
3.12.5 Fine Adjust of Field / Current in Holding Mode.................... 83
3.13 Persistent Switch Control................................................................... 83
3.13.1 Procedure for Initial Heating of the Switch .......................... 84
3.13.2 Procedure for Entering Persistent Mode .............................. 84
3.13.3 Procedure for Exiting Persistent Mode ................................. 87
3.13.4 Toggling the State of the Persistent Switch Heater.............. 90
3.14 Ramping Functions Example ............................................................ 91
3.15 Quench Detection ............................................................................... 92
3.15.1 External Quench Detection..................................................... 93
3.15.2 Disabling Internal Quench Detection .................................... 93
3.16 External Rampdown .......................................................................... 94
3.16.1 External Rampdown while in Persistent Mode .................... 94
3.16.2 External Rampdown while not in Persistent Mode .............. 96
3.17 Summary of Operational Limits and Default Settings..................... 96
Remote Interface Reference ............................................................ 99
4.1 SCPI Command Summary ................................................................. 99
4.2 Programming Overview.................................................................... 106
4.2.1 SCPI Language Introduction................................................ 106
4.2.2 SCPI Status System.............................................................. 106
4.2.3 Standard Event Register ...................................................... 109
4.2.4 Command Handshaking ....................................................... 110
4.3 RS-232 Configuration ....................................................................... 112
4.3.1 Serial Connector.................................................................... 112
4.3.2 Termination Characters........................................................ 112
Rev. 5 v
Table of Contents
4.4 Ethernet Configuration .....................................................................112
4.4.1 Ethernet Connector................................................................113
4.4.2 Termination Characters ........................................................113
4.5 Command Reference ..........................................................................114
4.5.1 System-Related Commands...................................................114
4.5.2 Status System Commands.....................................................115
4.5.3 SETUP Configuration Commands and Queries...................116
4.5.4 Protection Commands and Queries.......................................121
4.5.5 Ramp Configuration Commands and Queries......................126
4.5.6 Ramping State Commands and Queries...............................130
4.5.7 Switch Heater Command and Query ....................................131
4.5.8 Quench State Commands and Queries .................................132
4.5.9 Rampdown State Queries ......................................................132
4.5.10 Trigger Functions...................................................................134
4.6 Error Messages ..................................................................................136
4.6.1 Command Errors....................................................................136
4.6.2 Query Errors ..........................................................................137
4.6.3 Execution Errors ....................................................................138
4.6.4 Device Errors..........................................................................138
Service..............................................................................................141
5.1 System Component Maintenance .....................................................141
5.1.1 Model 430 Programmer Routine Maintenance.....................141
5.1.2 Model 08150PS Power Supply Routine Maintenance ..........141
5.1.3 Model 601 Energy Absorber Routine Maintenance..............141
5.2 Troubleshooting Hints .......................................................................141
5.2.1 Electrostatic Discharge Precautions .....................................142
5.2.2 The Model 430 does not appear to be energized...................142
5.2.3 FAILURE TO LOAD message displayed after power-up ....144
5.2.4 Power supply unstable - magnet voltage oscillates..............144
5.2.5 The power supply system will not charge the magnet.........145
5.2.6 Cannot charge the magnet at the selected ramp rate..........145
5.2.7 Cannot discharge the magnet at the selected ramp rate.....146
5.2.8 Cannot charge the magnet to desired field...........................146
5.2.9 Cannot place the magnet in persistent mode. ......................146
5.2.10 Cannot bring the magnet out of persistent mode.................147
5.2.11 The magnet quenches for no apparent reason......................147
5.2.12 Cannot lower the magnet field ..............................................147
5.2.14 The Model 601 FAULT LED energized with audible alarm148
5.2.15 There is excessive LHe boil-off during operation. ................148
5.2.16 Cannot display the magnetic field strength, only current...149
5.2.17 Cannot use remote communications commands. .................149
5.2.18 Magnet current drifts unacceptably while PSwitch cooling 150
5.2.19 Model 430 appears to lock up when connecting to network 150
vi Rev. 5
Table of Contents
5.3 Additional Technical Support........................................................... 150
5.4 Return Authorization........................................................................ 151
Appendix.......................................................................................... 153
A.1 Magnet Station Connectors ......................................................... 153
A.2 LHe Level / Temp Connectors ...................................................... 154
A.3 Current Transducer Signal Connector ........................................... 155
A.4 Current Transducer Power Connector ............................................ 156
A.5 Program Out Connector ................................................................... 157
A.6 Quench I/O Connector....................................................................... 158
A.6.1 External Quench Detection Input ........................................ 158
A.6.2 External Rampdown Input ................................................... 159
A.6.3 External Quench Detection Output ..................................... 160
A.7 Aux Inputs Connector....................................................................... 161
A.8 Ethernet Connector ...................................................................... 162
A.9 RS-232 Connector.............................................................................. 162
A.10 Abbreviations and Acronyms used in this Manual ......................... 163
A.11 Model 430 Programmer Specifications ......................................... 167
A.12 Power Supply Details........................................................................ 169
A.12.1 Model 08150PS Single Unit Electrical Specifications......... 170
A.12.2 Model 08150PS Single Unit Dimensional Specifications.... 172
A.13 Model 601 and Energy Absorption .................................................. 174
A.13.1 Model 601 Specifications....................................................... 174
A.13.2 Connecting Multiple Model 601 Energy Absorbers............. 174
A.13.3 Model 601 Energy Absorber Functional Description .......... 175
A.14 Remote Computer Communication with the Model 430................. 178
A.14.1 Communication via RS-232 .................................................. 178
A.14.2 Communication via Ethernet ............................................... 181
A.15 Upgrading the Model 430 Firmware via FTP ................................. 184
A.15.1 Hardware and Software Requirements................................ 184
A.15.2 Preparation............................................................................ 185
A.15.3 Procedure ............................................................................... 186
A.16 Upgrading the Model 430 Firmware via Flash Card Reader ......... 191
A.16.1 Hardware and Software Requirements................................ 191
A.16.2 Preparation............................................................................ 191
A.16.3 Procedure ............................................................................... 192
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Table of Contents
A.17 Model 430 Remote Control Application ............................................195
A.18 Model 430IP Power Supply Programmer .........................................198
A.19 Persistent Switch Operation Flowchart ...........................................201
Index ................................................................................................205
viii Rev. 5
1 List of Figures

List of Figures

Figure 1-1 Typical 05500PS-430-601 System Rack Layout..................................... 4
Figure 1-2 Model 08150PS Front Panel ................................................................... 7
Figure 1-3 Model 601 Front Panel Layout ............................................................... 8
Figure 1-4 The Four Regions, or Quadrants, of System Operation. ..................... 10
Figure 1-5 Dual-Quadrant System with Resistive Shunt...................................... 10
Figure 1-6 Dual-Quadrant System with Precision Current Transducer Option.. 11
Figure 2-1 Typical Model 05500PS-430-601 System Rack Interconnections ....... 17
Figure 2-2 Bipolar High-Stability System Interconnections ................................. 18
Figure 3-1 Default Display. ..................................................................................... 29
Figure 3-2 Numeric Keypad and Associated Keys ................................................. 32
Figure 3-3 Menu Navigation Keys .......................................................................... 34
Figure 3-4 Single Input Keys .................................................................................. 35
Figure 3-5 SHIFT-Key Functions ........................................................................... 39
Figure 3-6 Magnet Status LED Indicators. ............................................................ 46
Figure 3-7 Setup Menu Structure ........................................................................... 49
Figure 3-8 Example Power Supply Outputs........................................................... 52
Figure 3-9 Stability Setting vs. Magnet (with PSwitch) Inductance .................... 55
Figure 3-10 Typical Power Supply Self-Limits ........................................................ 57
Figure 3-11 Magnet Current Rating Set Within Supply Range.............................. 58
Figure 3-12 Example Current Limit Setup .............................................................. 59
Figure 3-13 Example Magnet Specification Sheet. .................................................. 79
Figure 3-14 Ramping to two different target field/current settings........................ 91
Figure 4-1 The Model 430 Programmer Status System. ..................................... 107
Figure 4-2 Asterisk Indicating Model 430 in Remote Mode ................................ 115
Figure A-1 Model 08150PS Dimensions - Front and Rear Views ........................ 172
Figure A-2 Model 08150PS Dimensions - Top and Side Views............................ 173
Figure A-3 Loop Voltages - Actively Discharging (with Model 601).................... 175
Figure A-4 Loop Voltages - Magnet Charging ...................................................... 176
Figure A-5 Loop Voltages - Magnet Charged (Steady State) ............................... 176
Figure A-6 Loop Voltages - Magnet Passively Discharging ................................. 177
Figure A-7 http:// - IP Address or System Name Entry ....................................... 196
Figure A-8 Initial Screen for Browser Access of the Model 430........................... 197
Figure A-9 Model 430IP Front Panel .................................................................... 198
Figure A-10 Browser Depiction of the Model 430 ................................................... 198
Figure A-11 http:// - System Name Entry ............................................................... 199
Figure A-12 Initial Screen for Browser Access of the Model 430IP....................... 199
Figure A-13 Browser Control of the Model 430IP .................................................. 200
Figure A-14 Persistent Switch Operation Flowchart, Page 1 ................................ 201
Figure A-15 Persistent Switch Operation Flowchart, Page 2 ................................ 202
Figure A-16 Persistent Switch Operation Flowchart, Page 3 ................................ 203
Rev. 5 ix
List of Figures
x Rev. 5
1 List of Tables

List of Tables

Table 1-1 Model 430 Front Panel Description ........................................................ 5
Table 1-2 Model 430 Zero Flux Version Rear Panel Description........................... 6
Table 1-3 Power Supply Front Panel Controls and Indicators ..............................7
Table 3-1 Description of Status Indicators ........................................................... 31
Table 3-2 Select Supply picklist values and associated parameters. .................. 51
Table 3-3 V-V Mode Input Range Picklist Values ................................................54
Table 3-4 Maximum Recommended Stability Setting Changes ......................... 56
Table 3-5 Example Setup Configuration...............................................................80
Table 3-6 Ramp modes and descriptions............................................................... 82
Table 3-7 Summary of Model 430 Programmer Limits and Defaults ................. 97
Table 4-1 Bit Definitions for the Status Byte Register ......................................108
Table 4-2 Bit Definitions for the Standard Event Register ............................... 110
Table 4-3 Return Values and Meanings for SUPPly:TYPE? Query.................. 117
Table 4-4 Return Values and Meanings for SUPPly:MODE? Query.................. 118
Table 4-5 Return Values and Meanings for STATE? Query............................... 131
Table 4-6 Model 430 Programmer Trigger Function Bit Definitions ................134
Table 5-1 V-V Mode Input Range Picklist Values ..............................................143
Table A-1 Magnet Station Connectors Pin Definitions.......................................153
Table A-2 LHe Level / Temp Connectors Pin Definitions...................................154
Table A-3 Current Transducer Signal Connector Pin Definitions..................... 155
Table A-4 Current Transducer Power Connector Pin Definitions ..................... 156
Table A-5 Program Out Connector Pin Definitions ............................................ 157
Table A-6 Quench I/O Connector Pin Definitions ...............................................158
Table A-7 Aux Inputs Connector Pin Definitions ...............................................161
Table A-8 Ethernet RJ-45 Connector Pin Definitions ........................................162
Table A-9 RS-232 Connector Pin Definitions ...................................................... 162
Table A-10 PC (DB9)-to-Model 430 RS-232 Cable Connections........................... 163
Table A-11 Abbreviations and Acronyms ..............................................................163
Table A-12 Model 430 Programmer Specifications @ 25°C ................................. 167
Table A-13 Model 08150PS Power Supply Specifications ....................................170
Table A-14 Model 601 Energy Absorber Specifications ........................................ 174
Rev. 5 xi
List of Tables
xii Rev. 5

Foreword

Purpose and Scope

This manual contains the operation and maintenance instructions for the American Magnetics, Inc. Model 05500PS-430-601 High-Stability Power Supply System with zero flux current sensing system. The user is encouraged to contact an authorized AMI Technical Support Representative for information regarding specific configurations not explicitly covered in this manual.

Contents of this Manual

Introduction introduces the reader to the functions and characteristics of the Model 430 Power Supply Programmer and the Power Supply System. It provides illustrations of the front and rear panel layouts as well as documenting the performance specifications. Additional information is provided in the form of system circuit diagrams.
Installation describes how the Model 430 Power Supply Programmer is unpacked and installed in conjunction with ancillary equipment in typical superconducting magnet systems. Block-level diagrams document the interconnects for various system configurations.
Operation describes how the Model 430 Programmer is used to control a superconducting magnet. All Model 430 Programmer displays and controls are documented. The ramping functions, persistent switch heater controls, and the quench detect features are also presented.
Remote Interface Reference documents all remote commands and queries available through the Model 430 Programmer RS-232 and Ethernet interfaces. A quick-reference summary of commands is provided as well as a detailed description of each.
Service provides guidelines to assist the user in troubleshooting possible system and Model 430 Programmer malfunctions. Information for contacting AMI Technical Support personnel is also provided.
Appendix provides additional details and/or procedures in the following areas:
1. Model 430 Programmer rear panel connectors.
2. Individual power supply unit specifications
Rev. 5 xiii
Foreword

General Precautions

3. Model 601 specifications
4. Establishing RS-232 or Ethernet communications with the Model
430.
5. Model 430 firmware upgrade.
6. Abbreviations and acronyms used in this manual.
7. Persistent switch operation (flow diagram).
General Precautions
Cryogen Safety
The two most common cryogenic liquids used in superconducting magnet systems are nitrogen and helium. Both of these cryogens are extremely cold at atmospheric pressure (321°F and 452°F, respectively). The following paragraphs outline safe handling precautions for these liquids.
Personnel handling cryogenic liquids should be thoroughly instructed and trained as to the nature of the liquids. Training is essential to minimize accidental spilling. Due to the low temperature of these materials, a cryogen spilled on many objects or surfaces may damage the surface or cause the object to shatter, often in an explosive manner.
Inert gases released into a confined or inadequately ventilated space can displace sufficient oxygen to make the local atmosphere incapable of sustaining life. Liquefied gases are potentially extreme suffocation hazards since a small amount of liquid will vaporize and yield a very large volume of oxygen-displacing gas. Always ensure the location where the cryogen is used is well ventilated. Breathing air with insufficient oxygen content may cause unconsciousness without warning. If a space is suspect, purge the space completely with air and test before entry. If this is not possible, wear a forced-air respirator and enter only with a co-worker standing by wearing a forced-air respirator.
Cryogenic liquids, due to their extremely low temperatures, will also burn the skin in a similar manner as would hot liquids. Never permit cryogenic liquids to come into contact with the skin or allow liquid nitrogen to soak clothing. Serious burns may result from careless handling. Never touch uninsulated pipes or vessels containing cryogenic liquids. Flesh will stick to extremely cold materials. Even nonmetallic materials are dangerous to touch at low temperatures. The vapors expelled during the venting process are sufficiently cold to burn flesh or freeze optic tissues. Insulated gloves should be used to prevent frost-bite when operating valves on cryogenic tanks. Be cautious with valves on cryogenic systems; the temperature extremes they are typically subjected to cause seals to fail frequently.
xiv Rev. 5
Foreword
General Precautions
In the event a person is burned by a cryogen or material cooled to cryogenic temperatures, the following first aid treatment should be given pending the arrival and treatment of a physician or other medical care worker:
1. If any cryogenic liquid contacts the skin or eyes, immediately flush
the affected area gently with tepid water (102°F 105°F, 38.9°C
40.5°C) and then apply cold compresses.
2. Do not apply heat. Loosen any clothing that may restrict circulation. Apply a sterile protective dressing to the affected area.
3. If the skin is blistered or there is any chance that the eyes have been affected, get the patient immediately to a physician for treatment.
Containers of cryogenic liquids are self pressurizing (as the liquid boils off, vapor pressure increases). Hoses or lines used to transfer these liquids should never be sealed at both ends (i.e. by closing valves at both ends).
When pouring cryogenic liquids from one container to another, the receiving container should be cooled gradually to prevent damage by thermal shock. The liquid should be poured slowly to avoid spattering due to rapid boil off. The receiving vessel should be vented during the transfer.
Introduction of a substance at or near room temperature into a cryogenic liquid should be done with great caution. There may be a violent gas boil­off and a considerable amount of splashing as a result of this rapid boiling. There is also a chance that the material may crack or catastrophically fail due to forces caused by large differences in thermal contraction of different regions of the material. Personnel engaged in this type of activity should be instructed concerning this hazard and should always wear a full face shield and protective clothing. If severe spraying or splashing could occur, safety glasses or chemical goggles along with body length protective aprons will provide additional protection.
The properties of many materials at extremely low temperatures may be quite different from the properties that these same materials exhibit at room temperatures. Exercise extreme care when handling materials cooled to cryogenic temperatures until the properties of these materials under these conditions are known.
Metals to be used for use in cryogenic equipment application must posses sufficient physical properties at these low temperatures. Since ordinary carbon steels, and to somewhat a lesser extent, alloy steels, lose much of their ductility at low temperatures, they are considered unsatisfactory and sometimes unsafe for these applications. The austenitic Ni-Cr alloys exhibit good ductility at these low temperatures and the most widely used
Rev. 5 xv
Foreword

Safety Summary

is 18-8 stainless steel. Copper, Monel®, brass and aluminum are also considered satisfactory materials for cryogenic service.
Magnet Quenches
When an energized superconducting magnet transitions from superconducting state to normal state, the magnet converts magnetic energy to thermal energy thereby rapidly converting the liquid helium to a vapor. When this phase transformation occurs, pressures can build rapidly in the cryostat due to the fact that one part of liquid helium will generate 782 parts of gaseous helium at STP (standard temperature and pressure). The cryostat must be designed to allow the generated vapor to rapidly and safely vent to an area of lower pressure. Cryostats are designed with pressure relief valves of sufficient capacity so as to limit the pressure transients within the container in order to prevent damage to the vessel. Operating a superconducting magnet in a cryostat without properly sized relief mechanisms or disabled relief mechanism is unsafe for the operator as well as for the equipment. If there is any doubt as to the sufficiency of the pressure relief system, contact the manufacturer of the magnet and cryostat for assistance.
Safety Summary
Superconducting magnet systems are complex systems with the potential to seriously injure personnel or equipment if not operated according to procedures. The use of cryogenic liquids in these systems is only one factor to consider in safe and proper magnet system operation. Proper use of safety mechanisms (pressure relief valves, rupture disks, etc.) included in the cryostat and top plate assembly are necessary. Furthermore, an understanding of the physics of the magnet system is needed to allow the operator to properly control the large amounts of energy stored in the magnetic field of the superconducting coil. The Model 430 Programmer has been designed with safety interlocks to assist the operator in safe operation, but these designed-in features cannot replace an operator’s understanding of the system to ensure the system is operated in a safe and deliberate manner.
Recommended Safety Equipment
First Aid kit
Fire extinguisher rated for class C fires
Cryogenic gloves
Face shield
Signs to indicate that there are potentially damaging magnetic fields
in the area and that cryogens are in use in the area.
xvi Rev. 5
Foreword
O
I
Safety Summary
Safety Legend
Instruction manual symbol: the product is marked with this symbol when it is necessary for you to refer to the instruction manual in order to protect against damage to the product or personal injury.
Hazardous voltage symbol.
Alternating Current (Refer to IEC 417, No. 5032).
Off (Supply) (Refer to IEC 417, No. 5008).
On (Supply) (Refer to IEC 417, No. 5007).
Warning
The Warning sign denotes a hazard. It calls attention to a procedure or practice, which if not correctly adhered to, could result in personal injury. Do not proceed beyond a Warning sign until the indicated conditions are fully understood and met.
Caution
The Caution sign denotes a hazard. It calls attention to an operating procedure or practice, which if not adhered to, could cause damage or destruction of a part or all of the product. Do not proceed beyond a Caution sign until the indicated conditions are fully understood and met.
Rev. 5 xvii
Foreword
Safety Summary
xviii Rev. 5

1 Introduction

1.1 Model 05500PS-430-601 Integrated Power Supply System Fea­tures
The AMI Model 05500PS-430-601 High-Stability Power Supply System is a sophisticated digitally-controlled power supply which allows an operator to manage a superconducting magnet system with unprecedented accuracy and ease of use. Integral components of the system include a Model 430 Programmer with zero flux current sensing system, Model 601 Energy Absorbers, and Model 08150PS Power Supplies. The AMI Model 05500PS-430-601 Power Supply System provides for a degree of flexibility and accuracy previously unavailable in an economical commercial product.

1.1.1 Digitally-Controlled

The Power Supply System is controlled by a microcomputer-based control­ler which controls all analog data conversion, display/keypad functions, communications I/O, generation of analog programming signals for the external power supply, and control law computations. The Power Supply System incorporates digital signal processing (DSP) functions that provide for accurate control, low drift, and flexibility of use.

1.1.2 Superior Resolution and Stability

The Model 430 Power Supply Programmer incorporates high-resolution converters to translate signals between the analog and digital domains. Precision instrumentation techniques and potentiometer-free designs are employed throughout the Model 430 Programmer to ensure accurate sig­nal translation for a wide range of conditions. The magnet current is sam­pled at 24-bit resolution in hardware and is software-programmable to 15­digits resolution. All pause and hold functions are performed in the digital domain which provides for excellent stability and drift of the programmed magnetic field.
For greater stability and accuracy, the Model 430 Programmer is config­ured with a zero-flux precision current measuring device instead of the standard resistive shunt. This option typically increases the system stabil­ity and accuracy by an order of magnitude. The power supply systems incorporating this technique are referred to as “high-stability” systems.

1.1.3 Intuitive Human-Interface Design

The Power Supply System was designed to simplify the interface where possible. All functions were analyzed and subsequently programmed so that the most commonly used functions are addressed with the least
Rev. 5 1
Introduction
Features
number of keystrokes. The menus are also presented in a logical fashion so that the operation of the Power Supply System is intuitive to the user.
The provision of a velocity-sensitive rotary encoder on the front panel also allows the operator to fine-adjust many of the operating parameters of the magnet system.

1.1.4 Flexibility

The Model 05500PS-430-601 system is configured as a two-quadrant high­stability power supply system which is able to both supply and remove electrical energy from the superconducting magnet system. The Power Supply System was engineered to be compatible with most magnet systems.

1.1.5 Standard Remote Interfaces

The Power Supply System provides an RS-232 serial port as well as an Ethernet port as standard features. All settings can be controlled via the remote interfaces and the front panel can be remotely locked to prevent accidental operation. The Power Supply System also provides trigger functions for data collection and/or logging during operation.

1.1.6 Programmable Safety Features

The Power Supply System is designed to be operated from the front panel of the Programmer or remotely with operational parameters which must not be exceeded for the given conditions of the system. Once set, should an operator inadvertently attempt to take the magnet system to an excessive magnetic field strength or charge at an excessive voltage, the Programmer will not accept the parameter and will alert the operator that a value was rejected because it was outside the user-defined limits.
In addition, each setup parameter can be individually selected for locking. A user-defined password is required to lock or unlock settings. This allows an administrator to set and password protect any critical parameters that should not be changed by the operator. Then the administrator can be confident that an operator will not subsequently change any of these critical parameters, and yet will be free to change any non-critical (unlocked) parameters.

1.1.7 Condition-Based Magnet Auto-Rampdown

The Power Supply System can be connected to an AMI Model 13x Liquid Helium Level Instrument to allow automatic rampdown of the magnet (even in persistent mode) should the liquid helium (LHe) level drop to a preset level. This feature ensures the magnet will be protected and not experience a quench should the LHe level reach an unsafe level for magnet operation. A single cable is required to use this feature and is covered in
2 Rev. 5
Introduction
General Description
more detail in section A.6.2 on page 159 of the Appendix. Contact AMI for more information.
In addition to low LHe level, this input to the Power Supply System can be used with other instrumentation as well. Other uses for this input include faults from a cryocooler, temperature instrumentation, etc.

1.1.8 Model 05500PS-430-601 General Description

A Model 430 Power Supply Programmer and five AMI Model 08150PS 1200 Watt unipolar voltage and current stabilized DC Power Supplies are configured with associated Model 601 Energy Absorbers to make up the +500 A, ±5 Vdc bipolar system designated as 05500PS-430-601. The power supplies are remotely controlled by the Model 430 Power Supply Programmer, and are connected in a parallel configuration to provide the rated current.
1
As a unipolar power supply, the Model 08150PS can only source power. However, when the five-power-supply combination is used in conjunction with five AMI Model 601 Energy Absorbers and controlled by a single AMI Model 430 Power Supply Programmer, the result is the bipolar Model 05500PS-430-601 integrated power supply system that is ideal for driving inductive loads such as large magnets or motors.
(not sink)
The power supplies are controlled by a ±10 Vdc remote analog signal supplied by the Model 430 Programmer and applied to the power supply analog inputs. Programming and control of the current loop (composed of the magnet, power supplies, Model 601 Energy Absorbers, and Model 430 Programmer zero flux device), is provided by a Model 430 ramp-generated current reference with parameters as set by the user in the Model 430. The Model 430 compares the measured current (via the zero flux device) with the current reference to provide precise closed-loop control of the actual current.
2
The power supply units are operated in voltage-voltage
programming mode, with the Model 430 Programmer output scaled to operate the power supply units over their available voltage output range. The Programmer signal will continually adjust the power supply output voltage to automatically regulate the power supply current; precise linear power supply current control will result as long as the system voltage and current demand do not exceed the total power supply rating or load limiting parameters.
1. The power supply is operating as a source if the current direction and voltage polar­ity are the same (i.e., the situation that would exist when supplying a resistive load). If the voltage polarity and current direction are opposite, the supply is operating as a sink.
2. Voltage reference controlling voltage output.
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Introduction
Figure 1-1. Typical 05500PS-430-601 System Rack Layout
System Rack

1.1.9 Power Supply System Rack Front Panel Layout

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Introduction
1 Power Indicator LED 8 Fine Adjust Knob
2 280 x 16 Dot Graphic VF Display 9 Persistent Switch Heater Control Key
3 Shift Indicator LED 10 Target Field Setpoint Key
4 Shift Key 11 Ramp/Pause Switch
5 4 Row x 3 Column Keypad 12 Menu Navigation and Data Entry Keys
6 Power Switch 13 Ramp to Zero Key
7 Magnet Status Indicator LEDs

Table 1-1. Model 430 Front Panel Description

Model 430 Front Panel

1.2 Model 430 Front Panel Layout

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Introduction

Table 1-2. Model 430 Zero Flux Version Rear Panel Description

Model 430 Rear Panel Layout

1.3 Model 430 Rear Panel Layout

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Introduction
Power Supply Front Panel Layout

1.4 Power Supply Unit Front Panel Layout

The power supply individual front panels contain the input ON/OFF circuit breakers and the OUTPUT indicators. The remaining front panel controls are not used in the Model 05500PS-430-601 configuration because the output is controlled by the Model 430 Programmer. Refer to Figure 1-2 and Table 1-3. for a description of front panel controls and indicators.

Figure 1-2. Model 08150PS Front Panel

Table 1-3. Power Supply Front Panel Controls and Indicators

Control or Indicator Function
POWER ON/OFF
Circuit Breaker
DC VOLTS display Four-digit LED display that shows output voltage.
Status
4 character display DC AMPERES display Four-dig it LED display that shows output current. DC OUTPUT indicator Green LED lights when DC output is enabled. LED is off when output is disabled.
Turns the power supply on or off. Circuit breaker provides input overload protection.
Displays active function or blinks for error messages. N orm al l y bla nk.
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Introduction

Figure 1-3. Model 601 Front Panel Layout

Model 601 Front Panel

1.5 Model 601 Energy Absorber Front Panel Layout

The Fault LED is the only device on the Model 601 front panel. If the Fault LED is not energized, the Model 601 is operating correctly. If the Fault LED is energized, then one or more of the internal energy absorbing elements has malfunctioned or power has been lost to the rear-panel power connector. An audible alarm will also sound when the Fault LED is energized.
Caution
If the system is in operation when an energy absorber fault occurs, a safe magnet system state (typically zero current or a cooled persistent switch in a connected magnet) should immediately be attained. Do not continue to operate the unit, and refer to the “Troubleshooting Hints” on page 141 for further direction.
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Introduction
Model 601 Front Panel
1.6 System Specifications @ 25°C
Magnet Current Control
Range: 0 to +500 A
Programming Accuracy: 25 mA
Stability: 5 mA after 10 min. at desired current
Minimum Ramp Rate: 100 μA/min
Maximum Ramp Rate: 30 A/sec
Output Voltage
Range: 0 to ±5 Vdc
Measurement Resolution: 10 mV
Load Inductance
Range: 0.5 to 100 H
Primary Power Requirements
Physical
Dimensionsa:
Approximate Weight: 330 lbm (150 kg)
Terminal Torque Limit: 48 lbf-in (5.4 N-m)
Environmental Limits
Ambient Temperature: 0 °C to 40 °C (32 °F to 104 °F)
Relative Humidity: 0 to 95%; non-condensing
a. H = height; W = width; D = depth
Range: 100 - 115 or 200 - 230 Vac ±10%
50 / 60 Hz, 7000 VA
47.2” H x 21.33” W x 24.5 D (1200 mm H x 542 mm W x 622 mm D)
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Introduction
20
-20
200-200
V
I
Positive Current
Flow Direction
Positive Voltage
Polarity
Positive Current
Flow Direction
Negative Voltage
Polarity
Negative Current
Flow Direction
Positive Voltage
Polarity
Negative Current
Flow Direction
Negative Voltage
Polarity
12
43

Figure 1-4. The Four Regions, or Quadrants, of System Operation.

Magnet
Coil(s)
Persistent
Switch
(optional)
Misc. Line Losses
Model 420
Shunt
Energy
Absorber
V
Unipolar
Power Supply
Current
Figure 1-5. Dual-Quadrant System with Resistive Shunt
430
Operating Characteristics

1.7 Operating Characteristics

The Model 430 Programmer has been designed to perform with var­ious power supplies to allow the user the greatest degree of system flexibility. The power supply and Programmer combination are cate­gorized by one of three forms: sin-
gle-quadrant, dual-quadrant, and four-quadrant. For sake of clarity,
the term quadrant is defined as one of four areas of a cartesian coordinate system where the abscissa is current and the ordi­nate is voltage. Refer to Figure 1-4.

1.7.1 Dual-Quadrant Operation

In the Model 05500PS-430-601 dual-quadrant Power Supply system, an energy absorber is added in series with the unipolar supply; this allows stored magnetic energy to be converted to thermal energy, thereby allowing much faster magnetic field reduction. This corresponds to operation in quadrants 1 and 4 of Figure 1-4. The disadvantage to this type of system is that energy is being dissipated in the energy absorbing element whenever current is flowing. This loss is sometimes a significant portion of the power required to operate the system.
The high-stability dual-quadrant precision current transducer-based variation, depicted in Figure 1-6, typically increases the system stability
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Introduction
Magnet
Coil(s)
Persistent
Switch
(optional)
Misc. Line Losses
V
Unipolar
Power Supply
Current
To Model 430
CURRENT TRANSDUCER
SIGNAL Connector
Current Transducer
Energy
Absorber
Figure 1-6. Dual-Quadrant System with Precision Current Transducer Option
Operating Characteristics
and accuracy (over that of the resistive shunt version) by an order of magnitude.
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Introduction
Operating Characteristics
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