Site power Documentation:

• 
  
• site power schematic (hagen 2004)(.pdf)
• site power schematic (work in progress felipe 2009) (.pdf)
  
• Substation documentation.
• Feb13: schematic of new switch gear installed at substation Feb13 (.pdf)
  
•  ABB eVD4 primary distribution circuit-breaker with integrated sensors and protection control unit Documentation
• label on our breaker:
• configuration code: xbafclannlc1
• x - has i/o extensions
• b - license level: feeder 2
• See eVD4 installation and service instructions pg 18 for specs.
  
• a - communication module type: 2 channel Ethernet
• f - CB type: fixed
• c - rated current of sensors: combisensor
• KEVCR 17.5 AA1
• Voltage:
• Voltage  Kn 10000:1
• accuracy: cl:1/3P
• voltage data: Ku 1.9/8h
• Current
• Current: Ipr: 250A
• accuracy: cI:1/5P
• current data: Usr:0.150/0.180V
  
• current: Ipr:250A, accuracy: cI:1/5P,
  
• l - voltage range: lv (48.. 60V dc)
• a- sensor type: K1 - 250 Amps
• n - RL1 presence: no
• n - RL2 presence: no
• l - Auto-reclosing: yes
• c -Communication protocal: IEC61850+MODBUS
• 1 - language:English
  
• type of apparatus: evd4 17.06. 75 (or 15?)
• Characteristics of the operating mechanism auxiliaries
• -mbc -mb01 -mas 48
  
• Installation and service manual (.pdf)
• Troubleshooting manual (.pdf)
  
• application manual (.pdf)
• connectivity package (.pdf)
• Engineering manual (.pdf)
  
• Modbus communications protocol manual (.pdf)
• IEC 61850 Communications Protocol Manual (.pdf)
  
• Breaker integrated protection RBX615. Operation manual (.pdf)
  
• Breaker integrated protection RBX615. Technical manual (.pdf)
• RBX615 - Parameters (.html)  Includes menu path to parameter.
  
• PCM600 (Protection and Control IED Manager) product guide (.pdf)
  

Power issues:

180421: Another slow transfer from generator to commercial.

    On 21apr18 there was a short power dip around 5am and the site switched to generator (the rented one). The commercial power came back with a minute or 2. The transfer switch put the site back on commercial power 2.7 hours later .
    The plots show the reading from the site main breaker for 21apr18 AM (.ps) (.pdf)

• Top: Phase to Phase voltage at input to breaker vs hour.
• black,red, green colors are the 3 phases.
• The dashed purple line is when the breaker closed and the site moved back to commercial power.
• The dashed blue line is 1/2 hour before the switch. This is the normal delay for the transfer switch to move from generator back to commercial. The commercial power needs to remain stable for this 1/2 hour.
• Middle: Current through the breaker.
• Each color is a different phase
• The purple line shows when the  breaker closed and current started flowing through the breaker.
• Bottom:  Power through breaker vs time
• black is KVA, red is active (resistive) power and green is reactive power.
• prior the transfer switch closing the breaker, there was around 60KV of reactive power recorded by the breaker (even when no current was flowing through the switch?). This is the same seen on 19apr18
  

Summary:

• Commercial power went off at 5 am on 21apr18 and returned 1 or 2 minutes later.
• AO switched back to commercial power (automatically) at 7:41am 21apr18. a bout 2.7 hours later
• For the transfer back to commercial power, the input voltage at the breaker needs to be stable for 1/2 hour. The monitor program reads the breaker values once a minute. It is possible that there were a number of short glitches that the monitor program missed (but i'm skeptical).
• If you look 1/2 hour  before the transfer generator -> commercial, phaseA of the phToPh voltages had dropped down to around 14.3KV (and then stayed below this value)
• I wonder if the transfer switch requires the phaseTophase voltages to be less than 14.3 KV before the 30 minute timer starts?
• Without a load, the commercial power at the input to the breaker tends to run above this value.
  

processing: x101/180421/pwrswitch.pro

180419: Site transfer switch after island wide blackout.

    On 18apr18 the power to the entire island went down around 10:20 am. The FEMA generator automatically switched in and ran the site.
The power in the local neighborhood returned around 12:30 am 19apr18. The AO transfer switch returned the site to commercial power around 8:22 19apr18.

    The local neighborhood and the ao power come from different lines. But i still thought it was a bit strange that AO waited 8 hours before it got commercial power back. I plotted up the data from the site main breaker to see what had occurred.

     The plot shows the reading from the site main breaker for 19apr18 AM (.ps) (.pdf)

• Top: Phase to Phase voltage at input to breaker vs hour.
• black,red, green colors are the 3 phases.
• The dashed blue line is when the input voltage to the breaker returned for the final time (before the transfer)
• Middle: Current through the breaker.
• Each color is a different phase
• The blue line shows when the voltage returned, the purple line is when the breaker closed and current started flowing through the breaker.'
• The delay from Voltage return to breaker closing was 30 minutes. This is the normal delay time for the transfer switch.
• Bottom:  Power through breaker vs time
• black is KVA, red is active (resistive) power and green is reactive power.
• prior the transfer switch closing the breaker, there was around 60KV of reactive power recorded by the breaker (even when no current was flowing through the switch?).

Summary:

• Commercial power went off at 10:20 am on 18apr18 and returned intermittently around 1:30 am 19apr18.
• AO switched back to commercial power (automatically) at 8:22 am 19apr18.
• The delay from voltage at switch input to transfer was 30 minutes.
• During the early morning there were stretches of  greater than 2 hours when there was voltage at the breaker input, but the site did not transfer to commercial power.
• The phase to phase voltages were up to 14.7KV during these 2 hours when no switch occurred. It must be that there is a lower and an upper limit before the transfer switch will move the site to commercial power.
• I don't quite understand why there is reactive power when no current is flowing?

processing: x101/180419/pwrswitch.pro

170608: Power outage. PhToGnd voltage-> 13KV. (top)

    The main breaker in the substation was replaced on 07jun16. On 08jun16 the following occurred.

• 08jun17:
  
• 15:33 I restarted the monitoring of the breaker
• 15:34  power outage..
  
• 09jun17: 22:00 back to commercial power.

The plots show the recorded data for this period (.ps) (.pdf):

• Data is sampled once a minute.
• The voltage data is sampled at the input to the breaker.
  
• Page 1: 08jun17  15:30 to 24:00
• Top frame: Phase to Phase voltages.
• Black Phase A to PhaseB voltage
• red  Phase B to PhaseC voltage
• green: phase C to Phase A voltage
• 2nd Frame:  Phase to Ground voltages. (we must have a Y connection).
• 3rd Frame: Current vs hour of day,. A blowup at the power outage.
• We only had 1 complete sample before things started to change.
• After 2 minutes, the current had gone to 0.. The site must have switched to the generators.
• Note. this gets done at  480Volts, after the  13kV has gone through the 13kV to 480V transformers.
• The breaker did not open during this period (all of the voltage protection in the breaker is currently disabled).
  
• Bottom frame:
• A blowup of the phase to ground voltages at the power outage.
• Page 2: 09jun17 00:00 to 12:00
  
• The site was on the generators the entire time.
  
• The substation  breaker and the transformers 13kV -> xx were still energized, but they supposedly did not have any load.
• Top: phase to phase voltages
• bottom: phase To ground voltages.
• 9:30  enoc opened the breaker (manually).
• The phaseA to Ground voltage went from 12KV to 0 volts.
  
• The other 2 phases remained unchanged.

Issues:

• Phase A voltage to ground did the following:
• 7.8 kV
• Load starts to drop:
• PhtoGndV -> 13KV for 7 minutes
• the load was 0 after about 2 minutes
• PhToGndV  13Kv -> 3.5Kv.. stayed there for about 15 minutes,
• PhToGndV  3.5Kv -> 12KV. stayed there till 09:30 the next day
• 09:30  main breaker manually opened. PhToGndV 12Kv -> 0V
  
• The breaker is a 13KV breaker. This is for the phase to phase voltages.
• We were putting 13KV between phase A and the common connection of the Y.
  
• I wonder if the breaker is setup to handle this voltage?
• When the breaker was opened, Phase A voltage to ground went from 12KV to 0v.
• The 12KV must have been coming from the AO side of the Breaker.. since opening the breaker, the input voltage went to 0.
  
• could the 430 recloser have been closed, and the 430 transformer (13kV -> 4160) was still connected to the outside line?
• Do we have some other problem with the components on the AO side of the breaker for Phase A?
• It would probably be a good idea for  us to get the substation programmed to open when we have voltage differences like this.
  
• It could then protect things on the AO side of the breaker.
• When doing this, we need to keep in mind:
• Would every power outage cause the breaker to open? Will it reclose automatically?
  
• What would happen during a lightning strike?
• If the breaker does open, then our transfer switch won't be able to switch back to public power until the breaker is closed.
  

Processing: x101/170608/spwr.pro

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