Download Advanced Tap Changer Control of Parallel Transformers based on

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Three-phase electric power wikipedia , lookup

Power engineering wikipedia , lookup

Transformer wikipedia , lookup

Buck converter wikipedia , lookup

Stray voltage wikipedia , lookup

Switched-mode power supply wikipedia , lookup

Rectiverter wikipedia , lookup

Distribution management system wikipedia , lookup

Voltage optimisation wikipedia , lookup

Opto-isolator wikipedia , lookup

Transformer types wikipedia , lookup

History of electric power transmission wikipedia , lookup

Electrical substation wikipedia , lookup

Mains electricity wikipedia , lookup

Alternating current wikipedia , lookup

Transcript
Advanced Tap Changer Control of
Parallel Transformers based on
IEC61850 GOOSE Service
Author: Jose Miguel Yarza
Co-author: Roberto Cimadevilla (presenter)
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
1
Overview





Interest of the application
Aim of Automatic Voltage Regulator (AVR)
AVRs working with Parallel Transformers
IEC 61850 based solution
RTDS tests
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
2
Field of Application
Transmission and Distribution substations with 2 or
more power transformers coupled on LV busbars
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
Growing interest
 Looking to the future, we can foresee:
 More demanding requirements to control Q
 Higher integration of Distributed Generation (DG)
 AVR (automatic voltage regulator) + OLTC (on-load tap
changer) are relevant in order to keep the voltage profiles
 AVR needs to work cooperatively with capacitor and
reactances to control voltage and Q
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
4
Purpose of AVR
 AVR commands the OLTC to keep stable the LV busbar
voltage according to a set-point, compensating voltage
variations due to:
 Voltage variations on transmission system
 Load and/or cosφ variations on the feeders
 Line impedance variations seen from the substation
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
5
Purpose of AVR
VBUS
Roberto Cimadevilla
 Settings:
 Voltage set-point (VCON)
 Insensitivity degree (GI)
 Delay time (T)
2013 CIGRE CANADA CONFERENCE
6
Control methods for parallel trafos.
 For the right performance of power transformers in parallel,
the coordination between AVR is a MUST:
 Master-follower method: for identical or very similar power
transformers
 Circulating current method: for power transformers with
different characteristics
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
7
Master-follower method
 Operation principle:
 One AVR behaves as master
 Master AVR controls the busbar voltage with the
traditional criteria for this function
 Rest of AVR (followers) follow master’s decisions to rise or
lower the tap
 Implementation modes:
 Following the “current” tap of master AVR (typically
admitting an offset)
 Following commands of master AVR’s
 As drawback, it might keep an unbalance situation if
taps are not normalized from the beginning
 Centralized (RTU, PLC) or decentralized
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
8
Master-follower method
 Exchange of information between AVR is essential for the
implementation of this method. For example:
 Master / follower role
 Taps
 Rise / lower commands
 Success or failure of the command
 Parallel group 1, 2,… (based on breakers and isolator
status)
 Blocking signals
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
9
Circulating current method
 Unequal tap positions between the parallel transformers
create a circulating current
 The circulating current is mainly reactive because
transformer impedance is basically inductive
 The operating principle is based on minimizing the
circulating current
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
10
Circulating current method
I1
I2
VPH
VPH
I circulating 
Roberto Cimadevilla
VTAP
X1  X 2
2013 CIGRE CANADA CONFERENCE
11
Circulating current method
 There are some basic data that needs to be exchanged
between AVRs:
 A magnitude that allows determining the reactive power
flow between transformers (Q, I)
 Parallel group 1, 2,… (based on breakers and isolator
status)
 Blocking signals
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
12
IEC61850 Based Solution
 Conventional solutions are normally based on wiring or
propietary protocols
 New solution uses a decentralized scheme based on
communication between AVRs by means of GOOSE
messages
 Each AVR will subscribe to the GOOSE of the rest AVRs
 GOOSE Control Block dataset will contain:
 Analog signal: Reactive power
 Digital signals: tap, parallel group, blocking signals, etc
 Control for up to, i.e., 5 transformers in parallel
Icirc
m
m
m
m

Q

Q

Q

Q
2
3
4
5
 I1m  RT C T1  sen 1  
m

V
1  RTVT 1

Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE




13
RTDS Testing for 3 parallel trafos.
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
14
10% Secondary Voltage Reduction
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
15
Start with Different Taps
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
16
Conclusions
 A solution based on IEC61850 GOOSE message for both the
circulating current and master-slave methods has been described
 The advantages regarding to the conventional solution are:
 Cost reduction due to less wiring and simpler engineering
(faster commissioning and less maintenance)
 Open solution that makes use of a more and more familiar
standard
 Flexibility that allows customizing the final solution easily
 Reliability provided by:
 GOOSE messages (Repetition-failure detection, information
about “quality”, low transmission time )
 Redundancy protocol (PRP, bonding)
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
17
Thank you
Roberto Cimadevilla
[email protected]
Jose Miguel Yarza
[email protected]
Roberto Cimadevilla
2013 CIGRE CANADA CONFERENCE
18