PDF Publication Title:
Text from PDF Page: 004
5000 Fault (Cont’d) Table 2. List of Faults (Cont’d) Bit # SPV FAULT RFC FAULT LFC FAULT 17 Pilot Injector #2 Valve Fault Pilot Injector #2 Valve Fault Not Used 16 Pilot Injector #1 Valve Fault Pilot Injector #1 Valve Fault Not Used 15 Not used Not used Not Used 14 Not used Not used Not Used 13 Not used Not used Not Used 12 Not used Not used Not Used 11 Not used Not used Not Used 10 Not used Self Test: Header/ Data CRC Not Used 9 Not used Self Test: phase C motor undercurrent Not Used 8 Not used Self Test: phase C motor overcurrent Pump feedback error? 7 Self Test: Header/ Data CRC Self Test: phase B motor undercurrent Pump overfrequency? 6 Self Test: Temp Sensor Self Test: phase B motor overcurrent Self Test: Fuel Temp Sensor? 5 Self Test: Solenoid Driver Self Test: phase A motor undercurrent Self Test: Board Temp Sensor 4 Self Test: Control Valve Self Test: phase A motor overcurrent Self Test: Heatsink Temp Sensor? 3 Self Test: Position Feedback Self Test: A/D Converter Self Test: A/D Converter 2 Self Test: A/D Converter Self Test: Personality Module Self Test: ROM fail 1 Self Test: Personality Module Self Test: RAM fail Self Test: Personality Module 0 Self Test: RAM fail Not Used Self Test: RAM fail Fault Decoding Process - Example The following example illustrates the decoding process for fuel subsystem faults. For this example we assume that the system is running on high pressure natural gas and therefore, has an SPV as the fuel control device. At the command line type ITASTR=1 The response is ITASTR, 0=0x0001 0x00800008 The number of interest is 00800008. Converting this number to binary using Table 1 yields the number 0000 0000 1000 0000 0000 0000 0000 1000. Counting from right to left and starting with bit 0 we see that there is a “1” in the location for bit 3 and bit 23. Referring to Table 2, this means that the SPV declared a Position Feedback fault in both the self-test mode (bit 3) and normal operation (bit 23). Once the bit numbers are identified, then refer to the following tables for detailed analysis of the faults identified by each bit. Observe Safety Precautions - Refer to Important Safety Instructions for Details Troubleshooting Guide 66 511521-002 This information is confidential and proprietary to Capstone. Neither this document nor the information contained herein shall be copied, disclosed to others, or used for any purposes other than the specific purpose for which this document was delivered.PDF Image | Capstone SERIES 5000 FAULT CODES
PDF Search Title:
Capstone SERIES 5000 FAULT CODESOriginal File Name Searched:
05_5000Faults.pdfDIY PDF Search: Google It | Yahoo | Bing
Capstone Turbine and Microturbine: Capstone microturbines used and new surplus for sale listing More Info
Consulting and Strategy Services: Need help with Capstone Turbine, sizing systems, applications, or renewable energy strategy, we are here to assist More Info
Container Lumber Dry Kiln: Since 1991 developing and innovating dry kilns using standard shipping containers More Info
Supercritical CO2 Lumber Dry Kiln: Compact fast drying in 3 days or less for small amounts of wood and lumber drying More Info
BitCoin Mining: Bitcoin Mining and Cryptocurrency... More Info
Publications: Capstone Turbine publications for microturbine and distributed energy More Info
FileMaker Software for Renewable Energy Developing database software for the renewable energy industry More Info
CO2 Gas to Liquids On-Demand Production Cart Developing a supercritical CO2 to alcohol on-demand production system (via Nafion reverse fuel cell) More Info
Stranded Gas for low cost power Bitcoin Mining Using stranded gas for generators may provide breakthrough low power costs for cryptocurrency miners. More Info
CONTACT TEL: 608-238-6001 Email: greg@globalmicroturbine.com (Standard Web Page)