Report No. T&S Planning – 2013-058 Page 1
Not to be reproduced without the permission of BC Hydro
Planning Assessment of BC to Alberta Transfer
Capability of the Existing System
Report No. Transmission & Stations Planning 2013-058
October 11th
, 2013
Transmission and Stations Planning
Report No. T&S Planning – 2013-058 Page 2
Not to be reproduced without the permission of BC Hydro
This page left blank intentionally
Report No. T&S Planning – 2013-058 Page 3
Not to be reproduced without the permission of BC Hydro
ACKNOWLEDGEMENTS
The study and report were carried out by BC Hydro Transmission & Stations
Planning in conjunction with Powertech Labs Inc.
BC Hydro: Steven Pai
Powertech Labs Inc.: Dr. Khosro Kabiri
Report No. T&S Planning – 2013-058 Page 4
Not to be reproduced without the permission of BC Hydro
CONTENTS
Executive Summary .................................................................................................... 6
1. Introduction .............................................................................................. 7
2. Study Data and conditions ....................................................................... 7
2.1 Heavy Summer............................................................................. 7
2.2 Heavy Winter ................................................................................ 9
3. Study Methodology ................................................................................ 10
3.1 Power Flow Analysis .................................................................. 10
3.2 Contingency Power Flow Analysis .............................................. 11
3.3 Transient Stability Analysis ......................................................... 11
4. Study Results ......................................................................................... 12
4.1 Heavy Summer........................................................................... 12
4.2 Heavy Winter .............................................................................. 13
5. Conclusion ............................................................................................. 16
Appendix A – Pre-outage Power Flows..................................................................... 17
Appendix B – Contingencies ..................................................................................... 28
Appendix C – Power Flow Contingency Results ....................................................... 30
Appendix D – Transient Stability Performance Plots ................................................. 36
Report No. T&S Planning – 2013-058 Page 5
Not to be reproduced without the permission of BC Hydro
DISCLAIMER
This Report was prepared solely for internal purposes. All parties other than BC Hydro are third parties. BC Hydro does not represent, guarantee or warrant to any third party, either expressly or by implication:
(a) the accuracy, completeness or usefulness of,
(b) the intellectual or other property rights of any person or party in, or
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COPYRIGHT NOTICE This Report is copyright by BC Hydro in 2013 and may not be reproduced in whole or in part without the prior written consent of BC Hydro.
Report No. T&S Planning – 2013-058 Page 6
Not to be reproduced without the permission of BC Hydro
EXECUTIVE SUMMARY
The planning assessment of BC to Alberta (Path1) transfer capability of the existing BC Hydro
transmission system was carried out at three different levels, 850 MW, 1100 MW and 1200 MW
based on N-0 (Category A) and N-1 (Category B) considerations. System limitations outside BC
that could affect the transfer limit were not included in the study. Impact of contingencies in
Alberta or US was not studied. The assessment was done both on the steady state and transient
stability performance. The study cases cover the heavy summer and heavy winter conditions with
Kootenay area generation varied as a sensitivity parameter. The impact of extremely low
probability simultaneous double contingencies (Category C) is not included in this assessment, but
will be addressed in a future study. The applicable remedial action schemes in response to the
various contingencies were simulated according to operation rules and requirements.
The findings based on Category A and B performance requirement of the selected BC Hydro
system conditions are listed below:
1. No unacceptable steady-state or dynamic performance was observed for 850 MW BC to
AB transfer under both summer and winter peak loading conditions.
2. Under summer loading conditions, 1200 MW BC to AB transfer does not cause Category
A or B performance violations.
3. Under winter loading conditions, 1200 MW BC to AB transfer does not cause Category A
or B violations, however the voltage performance was marginally acceptable. It would be
prudent to adopt 1100 MW as the BC to AB transfer limit until detailed operation planning
studies are completed.
Report No. T&S Planning – 2013-058 Page 7
Not to be reproduced without the permission of BC Hydro
1. INTRODUCTION
The WECC Path rating catalogue shows the Alberta-British Columbia path (Path 1) ratings of
1000 MW East to West and 1200 MW West to East. The 2007 BC Transmission Corporation
(BCTC) studies1,2
identified BC to Alberta transfer limit of 850 MW. This study aims at updating
the 2007 studies using the latest system information and model based on BC Hydro (BCH) system
considerations. Systems outside BC are modeled but not included in the study scope. The focus of
the study is on the West to East transfer for which all the prepared study cases have power flows
from BC to Alberta (AB).
The study cases are developed from two WECC base cases; one for heavy summer and the other
for heavy winter conditions. These base cases and the study cases developed from them are
introduced in more detail in Section 2. Then in Section 3 the methodology employed in assessing
the system conditions is explained. The study findings are presented in Section 4 followed by the
conclusion in Section 5. The appendices contain the detailed study information and results of
simulations of selected cases.
2. STUDY DATA AND CONDITIONS
The data used in this study include the power flow and dynamic data models of the WECC system
and contingency files of BCH system.
2.1 Heavy Summer
The 2013 heavy summer base case3 together with dynamic files were obtained from the Montana
Alberta Tie Line (MATL) study group. The case is based on a 2013 WECC case in which the
MATL path is added and the case is tuned for study on MATL. The BC Hydro (area 50) load in
this base case is 7727 MW. Several power flow cases were derived from this base case by
adjusting the flow from BC to Alberta to different levels. The flow from BC to US was also
adjusted to the study conditions.
In order to assess the effect of area generation dispatch on the system, local generation in South
Interior near Selkirk (SEL) substation was varied which include Kootenay Canal (KCL) and Seven
Mile (SEV) generating stations. Figure 2-1 shows the Selkirk area connections. The total
generation capacity at KCL is 580 MW and at SEV is 800 MW. Reducing generation at these
locations means that the power transferred to Alberta would mainly come from Ashton Creek
(ACK) and Vaseux Lake (VAS) substations through 5L91 and 5L96 respectively.
64 1 “Point to Point US to BC, BC to Alberta and wheel through US to Alberta - System Impact Study”
2 “System Impact Study For Increasing Firm ATC From BC to Alberta and From BC Interior to the US”
3 13hs_3s_Case2b_2.raw
Report No. T&S Planning – 2013-058 Page 8
Not to be reproduced without the permission of BC Hydro
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112
Figure 2-1: SEL area system connections
Table 2-1 shows the heavy summer cases that have been set up for the study, with BC exporting
power to both Alberta and the US. In all the cases, MATL path is in service and the MATL phase
shifter is adjusted to have negligible flow. The associated power flow plots are included in
Appendix A.
Table 2-1: Heavy summer study cases and power flows (MW)
Case BC to AB BC to US KCL Gen SEV Gen SEL
Interface MATL
(S to N)
13hs_case1 854 1020 570 580 480 -1
13hs_case1b 851 1200 0 0 -651 0
13hs_case2a 1098 1000 130 83 -697 1
13hs_case3 1201 1033 570 580 115 0
13hs_case3a 1200 999 150 170 -699 0
Note that the SEL interface in Table 2-1 is defined as follows4:
SEL Interface = 5L91 SEL + 5L96 SEL + 2L112 NLY + 48L KET
64 4 According to Attachment 1 of 7T-34, Effective Date: 03 January 2013, Page 7 of 69.
Report No. T&S Planning – 2013-058 Page 9
Not to be reproduced without the permission of BC Hydro
Where ‘5L91 SEL’ is the flow in the 500 kV line from SEL to ACK measured at SEL. ‘5L96
SEL’ is the flow in the 500 kV line from SEL to VAS measured at SEL. ‘2L112 NLY’ is the flow
in the 230 kV line from Nelway (NLY) to Boundary (BDY) measured at NLY, and ‘48L KET’ is
the flow in the 161 kV line from Kettle Valley (KET) to Bentley Terminal Station (BEN)
measured at KET.
A negative ‘SEL Interface’ flow means that the power flows from South Interior West to South
Interior East. The west to east flow is normally kept below 700 MW for the present system.
2.2 Heavy Winter
The heavy winter base case5 together with dynamic files were from Powertech Labs who prepared
the case from a 2013/14 WECC case for conducting the Path 3 (tie between the BC and US)
studies. The BC Hydro (area 50) load in this base case is 10752 MW. Several pre-outage power
flow study cases were derived from this base case by adjusting the flow from BC to Alberta to
different levels. The flow from BC to US was also modified to match the intended study
conditions.
Table 2-2 shows heavy winter cases set up for the study in which BC is exporting to Alberta and
importing from the US (negative numbers in BC to US Column indicate import into BC). The
MATL phase shifter is at the tap limit in Case 2a, Case 3, and Case 3b. The associated power flow
plots are included in Appendix A.
Table 2-2: Heavy winter study cases and power flows (MW)
Case BC to AB BC to US KCL Gen SEV Gen SEL
Interface MATL
(S to N)
13hw2ae_case1 868 -850 494 775 543 0
13hw2ae_case1a 850 -850 0 0 -692 0
13hw2ae_case2a 1099 -1095 69 195 -691 59
13hw2ae_case3 1204 -833 494 775 186 20
13hw2ae_case3b 1207 -1204 140 234 -698 101
64 5 13hw2ae_NI_500+400-MTL_300-PSE_785.pfb
Report No. T&S Planning – 2013-058 Page 10
Not to be reproduced without the permission of BC Hydro
3. STUDY METHODOLOGY
The study looked into both the pre and post contingency steady-state conditions and the transient
stability performance of the BCH system. The pre-outage power flow cases for the study were
tuned to obtain acceptable voltage profile across the system for various transfer levels and
generation dispatches. The study is focused on the area close to the intertie, i.e. South Interior
West and South Interior East divisions of the BCH system.
3.1 Power Flow Analysis
Both the pre-outage and post-outage power flows are solved with the following control commands
turned on:
- Area Interchange Flow Control
- Continuous Shunt Adjustment
- Discrete Shunt Adjustment
- Transformer Tap Changer Adjustment
- Phase Shifter Adjustment
Distinctions are made between the manually controlled vs. automatically controlled devices. For
the pre-outage cases, all controlled devices were turn on. Whereas in the post contingency power
flow simulations, only automatically controlled actions were allowed.
When the Area Interchange control flag is on, the power flow solver adjusts the net exchange from
each area over its tie lines such that the net exchange power specified for the area is met. In this
solution method each area must have a swing bus to be used during the iterations. The difference
between generation on the one hand and the load and export on the other hand is absorbed by the
area swing bus.
Continuous Shunt Adjustment flag pertains to the static VAR compensators. The MVAr outputs of
these fast-acting shunts are adjusted continuously within their given ranges in order to regulate the
voltage of their specified controlled buses.
When the Discrete Shunt Adjustment flag is on, the shunts specified as ‘discrete’ in the model are
adjusted in a stepwise manner in order to regulate the voltage of their specified controlled buses. It
should be noted that shunts which are specified as ‘fixed’ or ‘frozen’ do not participate in this
control action. The manually switched shunts were frozen in solving the post-outage power flows.
With the Transformer Tap Changing flag on, adjustments are done to the tap ratios of adjustable
two-winding and three-winding transformers during iterations in order to regulate their controlled
bus voltages. The manually operated tap changers were disabled in solving the post-outage power
flows.
Phase shifters are transformers whose controlled variable is the real power. With the Transformer
Tap Changing flag on, adjustments are done to angle shift between the primary and secondary
Report No. T&S Planning – 2013-058 Page 11
Not to be reproduced without the permission of BC Hydro
windings in order to regulate the real power flow through the phase shifter within the specified
range. Since the Nelway phase shifter is normally not on automatic MW flow control mode, its
controller was blocked for the post contingency power flow.
After the power flow was solved with the above parameters, a manual check was done on the
power flow levels and voltage magnitudes in BC to ensure they are in the acceptable ranges.
3.2 Contingency Power Flow Analysis
The list of BCH contingencies studied is provided in Appendix B. The contingency names
represent the element or elements that are directly affected by the contingency and are tripped out
as a result. Most of the N-1 contingencies analyzed in this study only affect a single element.
However, some N-1 contingencies involve more than one element as explained below.
For example, the ‘SEL T2 & T3’ contingency and ‘CBK T2 & T6’ contingency each involve the
loss of two transformers because they are in the same protection zone.
Some contingencies involve Remedial Action Schemes (RAS) that would subsequently trigger
actions on other elements in the system. The RAS actions are simulated in accordance with BCH
operating orders. Note that the 5L92 or 5L94 contingency would cause the MATL tie to trip due to
the high Path 1 flows which consequently would result in the Alberta system to become islanded.
3.3 Transient Stability Analysis
Time domain simulations were performed for the same set of N-1 contingencies as described in
Section 3.2. Equipment switching sequence and timings were applied in accordance with the
protection settings of various schemes, such as equipment within the same protection zones, auto
reclose, and RAS actions.
Report No. T&S Planning – 2013-058 Page 12
Not to be reproduced without the permission of BC Hydro
4. STUDY RESULTS
In this section the study results are presented with separate sections for heavy summer and heavy
winter conditions.
4.1 Heavy Summer
Pre-outage Power Flows
With Path 1 flow at about 850 MW, the steady-state power flow voltages on the 500 kV and 230
kV levels in the BC Hydro system can be maintained at the preferred levels. However, as Path 1
flow is increased from 850 MW to 1200 MW the voltages around Cranbrook (CBK) and Natal
(NTL) area drop to lower values.
Table 4-1 lists the pre-outage study case voltages at CBK and NTL for three levels of BC to
Alberta transfer. At 1200 MW of transfer the voltage at NTL can be as low as 0.95 p.u. The
associated power flow plots of these cases are displayed in Appendix A.
Table 4-1: Pre-outage Voltage levels at CBK and NTL, heavy summer conditions
Case BC-AB Flow CBK 500 kV CBK 230 kV NTL 230 kV
[MW] [p.u.] [p.u.] [p.u.]
Heavy Summer 1 850 1.039 1.025 1.0154
Heavy Summer 1b 850 1.036 1.023 1.014
Heavy Summer 2a 1100 1.006 0.994 0.978
Heavy Summer 3 1200 0.987 0.974 0.942
Heavy Summer 3a 1200 0.988 0.974 0.946
Post Outage Power Flows
The two single contingencies that produced the worst post contingency power flow results are
5L91 and 2L294. Their respective results for the above cases are shown in Tables 4.2 and 4.3. Table 4-2: Post 5L91 Contingency Voltage levels at CBK and NTL, heavy summer conditions
Case BC-AB Flow CBK 500 kV CBK 230 kV NTL 230 kV
[MW] [p.u.] [p.u.] [p.u.]
Heavy Summer 1 850 1.032 1.018 1.010
Heavy Summer 1b 850 1.032 1.019 1.010
Heavy Summer 2a 1100 0.994 0.983 0.968
Heavy Summer 3 1200 0.973 0.962 0.932
Heavy Summer 3a 1200 0.968 0.956 0.931
Table 4-3: Post 2L294 Contingency Voltage levels at CBK and NTL, heavy summer conditions
Report No. T&S Planning – 2013-058 Page 13
Not to be reproduced without the permission of BC Hydro
Case BC-AB Flow CBK 500 kV CBK 230 kV NTL 230 kV
[MW] [p.u.] [p.u.] [p.u.]
Heavy Summer 1 850 1.033 1.020 1.012
Heavy Summer 1b 850 1.029 1.017 1.009
Heavy Summer 2a 1100 1.000 0.989 0.974
Heavy Summer 3 1200 0.968 0.956 0.922
Heavy Summer 3a 1200 0.968 0.956 0.932
Loss of 5L92 or 5L94 causes Alberta disconnected from BC which would result in MATL line
tripped and subsequent islanding of Alberta system. Generator shedding in BC was applied to
reduce the surplus power. No violation was observed in post contingency power flows.
Post contingency power flow voltages of cases 3 & 3a are displayed in Appendix C – Power Flow
Contingency Results.
Transient Stability Performance
No transient stability issues were observed for the studied system conditions after applying the
contingencies listed in Appendix B. Selected transient stability performance cases are listed in
Table 4-4 with their time domain simulation plots displayed in Appendix D.
Table 4-4: Transient Stability Plots, heavy summer conditions
Case BC-AB Flow [MW] Contingency Name Plots
Heavy Summer 3a 1200 5L91, 3ph flt@SEL500 HS1200_5L91
Heavy Summer 3a 1200 5L92, 3ph flt@CBK500 HS1200_5L92
Heavy Summer 3a 1200 2L294, 3ph flt@CBK230 HS1200_2L294
4.2 Heavy Winter
Pre-outage Power Flows
The BCH load is significantly higher in heavy winter than in heavy summer cases, resulting in
more stressed system conditions. With Path 1 flow at 850 MW, pre-outage steady state power flow
voltages on the 500 kV and 230 kV levels in the BC Hydro system can be maintained within the
acceptable range. However, compared to heavy summer conditions these voltages are generally
lower. Increasing the transfer to 1100 MW or 1200 MW would significantly reduce the area
voltages. Table 4-5 lists the pre-outage voltages at CBK and NTL for three different levels of BC
to Alberta flow.
Report No. T&S Planning – 2013-058 Page 14
Not to be reproduced without the permission of BC Hydro
Table 4-5: Pre-outage Voltage levels at CBK and NTL, heavy winter conditions
Case BC-AB Flow [MW]
CBK 500 kV [p.u.]
CBK 230 kV [p.u.]
NTL 230 kV [p.u.]
Heavy Winter 1 850 1.020 1.003 0.988
Heavy Winter 1a 850 1.025 1.009 0.993
Heavy Winter 2a 1100 0.985 0.971 0.952
Heavy Winter 3 1200 0.950 0.933 0.913
Heavy Winter 3b 1200 0.961 0.945 0.926
Post Outage Power Flows
Similar to the summer cases, the two single contingencies that produced the worst post
contingency power flow results were 5L91 and 2L294. Their respective results for the above cases
are shown in Tables 4.6 and 4.7 below. As expected the performance of winter cases are worse
than the summer cases. At 1200 MW transfer the voltage performance is only marginally
acceptable. Table 4-6: Post 5L91 Contingency Voltage levels at CBK and NTL, heavy winter conditions
Case BC-AB Flow [MW]
CBK 500 kV [p.u.]
CBK 230 kV [p.u.]
NTL 230 kV [p.u.]
Heavy Winter 1 850 1.006 0.989 0.973
Heavy Winter 1a 850 1.020 1.006 0.991
Heavy Winter 2a 1100 0.961 0.947 0.925
Heavy Winter 3 1200 0.932 0.917 0.896
Heavy Winter 3b 1200 0.942 0.928 0.909
Table 4-7: Post 2L294 Contingency Voltage levels at CBK and NTL, heavy winter conditions
Case BC-AB Flow [MW]
CBK 500 kV [p.u.]
CBK 230 kV [p.u.]
NTL 230 kV [p.u.]
Heavy Winter 1 850 1.009 0.996 0.981
Heavy Winter 1a 850 1.018 1.006 0.991
Heavy Winter 2a 1100 0.964 0.951 0.931
Heavy Winter 3 1200 0.928 0.915 0.895
Heavy Winter 3b 1200 0.941 0.928 0.910
Similar to the summer cases, loss of 5L92 or 5L94 causes Alberta disconnected from BC which
would result in MATL line tripped and subsequent islanding of Alberta system. Generator
shedding in BC was applied to reduce the surplus power in the simulations. No violation was
observed in post disturbance power flows of these contingencies.
Post contingency power flow voltages of cases 2a, 3 & 3b are displayed in Appendix C – Power
Flow Contingency Results.
Report No. T&S Planning – 2013-058 Page 15
Not to be reproduced without the permission of BC Hydro
Transient Stability Performance
No transient stability issues were observed for the studied system cases after applying the
contingencies in Appendix B except marginal performance at 1200 MW BC to AB transfer,
particularly when Kootenay area generations are high. Selected transient stability performance
cases are listed in Table 4-8 with their time domain simulation plots displayed in Appendix D.
Table 4-8: Transient Stability Plots, heavy winter conditions
Case BC-AB Flow [MW] Contingency Name Plots
Heavy Winter 2a 1100 5L91, 3ph flt@SEL500 HW1100_5L91
Heavy Winter 3 1200 5L91, 3ph flt@SEL500 HW1200_5L91
Heavy Winter 3b 1200 5L91, 3ph flt@SEL500 HW1200_5L91
Heavy Winter 3b 1200 5L92, 3ph flt@CBK500 HW1200_5L92
Heavy Winter 3b 1200 5L94, 3ph flt@CBK500 HW1200_5L94
Heavy Winter 3b 1200 2L294, 3ph flt@CBK230 HW1200_2L294
Given the poor performance of 1200 MW BC to AB transfer, It would be prudent to adopt 1100
MW transfer as an acceptable limit for winter conditions before detailed operation planning
studies are completed.
Report No. T&S Planning – 2013-058 Page 16
Not to be reproduced without the permission of BC Hydro
5. CONCLUSION
The steady-state and transient stability of the BC Hydro system were assessed for three different
levels of BC to Alberta transfers: 850 MW, 1100 MW, and 1200 MW based on heavy summer and
heavy winter loading conditions of WECC base cases. Single contingencies (Category B) in the
South Interior West and South Interior East regions of BCH were applied for the assessment. No
contingency in Alberta or US was applied.
The findings based on Category A and B performance requirements are listed below:
1. No unacceptable steady-state or dynamic performance was observed for 850 MW BC to
AB transfer under both summer and winter peak load conditions.
2. Under summer loading conditions, 1200 MW BC to AB transfer does not cause Category
A or B performance violations.
3. Under winter loading conditions, 1200 MW BC to AB transfer does not cause Category A
or B violations, however the voltage performance was only marginally acceptable. It would
be prudent to adopt 1100 MW as the BC to AB transfer limit until detailed operation
planning studies are completed.
Report No. T&S Planning – 2013-058 Page 17
Not to be reproduced without the permission of BC Hydro
APPENDIX A – PRE-OUTAGE POWER FLOWS
The pre-outage power flows of study cases listed in Tables 2-1, 2-2, 4-1, and 4-5 are displayed
below.
Report No. T&S Planning – 2013-058 Page 18
Not to be reproduced without the permission of BC Hydro
50
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75.02
-267.98
-0.00
-0.00
-82.22
366.73
102.59
-366.43
-175.3
0
175.9
2
2L293
9.5
8
-8.4
1
80640
1.0276AAL 2T3 230.
-167.3
2169.9
02
L2
94
11.5
5-7
.25
-0.00
80640
-175.3
0
-167.3
2169.9
0
175.9
2
1.0276
2L
29
411.5
5-7
.25
AAL 2T3 230.
2L293
9.5
8
-8.4
1
-0.00
-82.22
366.73
102.59
-366.43
50
70
2
1.0
482
AC
K 5
00
5
00.
0.00
0.00
51
13
4
1.0
601
VA
S 5
00
5
00.
50
78
8
1.0
360
KC
L 2
30
2
30.
0.10
0.21
280.24
-275.6
8
2L295
-38.80
61.3
3
50
70
2
51
13
4
50
78
8
280.24
-275.6
8
1.0
360
2L295
-38.80
61.3
3
KC
L 2
30
2
30.
1.0
601
VA
S 5
00
5
00.
1.0
482
AC
K 5
00
5
00.
279.98
-275.4
3
2L299
-38.73
61.2
2
CBK
279.98
-275.4
3
0.10
0.21
SEL
2L299
-38.73
61.2
2
ACK
VAS
KCL
AAL
NLY
0.0
0
0.0
0
0.0
0
0.0
0
50789
1.0276AAL 2T1 230. 146.3
2
-143.63
2L
29
4
-17.9
6
18.60
167.3
2-1
67.3
2
-11.4
511.5
0
50785
1.0397SEV 2T1 230.
50789
146.3
2
50785
167.3
2-1
67.3
2
-143.63
1.0276
2L
29
4
1.0397SEV 2T1 230.
-11.4
511.5
0-1
7.9
6
18.60
AAL 2T1 230.
289.2
3-2
89.0
22
L2
21
-46.0
146.9
0
51350
1.0397SEV 2T3 230. 289.2
5-2
89.0
52
L2
22
-42.2
243.1
0
-30.7
5
30.77
5L
91
-139.4
8
-31.56
51350
289.2
3
289.2
5
-30.7
5
30.77
-289.0
5
-289.0
2
1.0397
0.00
0.00
2L
22
2
5L
91
-139.4
8
-31.56
-42.2
243.1
0
SEV 2T3 230.
2L
22
1
-46.0
146.9
0
-421.45
423.9
8
5L
96
-22.53
-166.3
5
SEV40146
1.0400BOUNDRYW 230.
53.5
7-5
3.5
62
L1
12
-9.2
78.6
0
50787
1.0155NTL 230 230.
-421.45
40146
423.9
8
50787
53.5
7-5
3.5
6
5L
96
1.0400
1.0155NTL 230 230.
2L
11
2
-9.2
78.6
0
BOUNDRYW 230.
-22.53
-166.3
5
-6.47
0.1
4
2L
11
3-1
04.2
0
105.37
-6.47
0.1
4
2L
11
3
LA
NG
DO
N2
500.
54
15
8
1.0
438
-104.2
0
105.37
LA
NG
DO
N2
500.
54
15
8
1.0
438
-33.36 92.28
5L94802.71 -785.34
-33.36 92.28
5L94802.71 -785.34
Interface: AB-BC: Path-1
Total From MW Flow: 854.49 MW
Interface: BC-US: Path-3
Total From MW Flow: 1020.29 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: 1.14 MW
54
23
2
CO
LE
MA
N7
138.
1.0
296
54
23
2
CO
LE
MA
N7
138.
1.0
296
50
77
6
NT
L 1
38
1
38.
1.0
400
50
77
6
NT
L 1
38
1
38.
1.0
400
48.66
-7.78
-47.88
7.43
1L27548.66
-7.78
-47.88
7.43
1L275
50
83
0
BC
K 2
74P
138.
1.0
103
50
83
0
BC
K 2
74P
138.
1.0
103
54
32
9
PO
CA
TE
R7
138.
1.0
435
54
32
9
PO
CA
TE
R7
138.
1.0
435
3.12
-1.81
-3.12
-1.16
1L2743.12
-1.81
-3.12
-1.16
1L274
13hs_case1_P1_08505
07
69
KC
L 1
3G
1
13.8
1.0
303
142.50
-2.171
50
76
9
KC
L 1
3G
1
13.8
1.0
303
142.501
-2.17
50
77
0
KC
L 1
3G
2
13.8
1.0
303
142.50
-2.172
50
77
0
KC
L 1
3G
2
13.8
1.0
303
142.502
-2.17
50
77
1
KC
L 1
3G
3
13.8
1.0
299
142.50
-2.173
50
77
1
KC
L 1
3G
3
13.8
1.0
299
142.503
-2.17
50
77
2
KC
L 1
3G
4
13.8
1.0
300
142.50
-2.174
50
77
2
KC
L 1
3G
4
13.8
1.0
300
142.504
-2.17
50766
SEV 13G1 13.8 1.0327
145.0
0
-9.7
11
50766
SEV 13G1 13.8 1.0327
145.0
01
-9.7
1
50767
SEV 13G2 13.8 1.0276
145.0
0
-7.5
52
50767
SEV 13G2 13.8 1.0276
145.0
02
-7.5
5
50768
SEV 13G3 13.8 1.0330
145.0
0
-9.2
43
50768
SEV 13G3 13.8 1.0330
145.0
03
-9.2
4
51036
SEV 13G4 13.8 1.0332
145.0
0
-11.7
24
51036
SEV 13G4 13.8 1.0332
145.0
04
-11.7
2
50786
INV 230 230. 1.0628
50786
INV 230 230. 1.0628
34.44
-49.43
-34.0
2
27.0
0
2L
25
8
34.44
-49.43
-34.0
2
27.0
0
2L
25
8
Report No. T&S Planning – 2013-058 Page 19
Not to be reproduced without the permission of BC Hydro
50
79
1
1.0
356
CB
K 5
00
5
00.
50822
1.0401NLY 2PS2 230.
50784
1.0371NLY 230 230.
-150.8
5151.1
1
16.2
3-7
.31
50
79
1
50822
50784
-150.8
5151.1
1
1.0371
16.2
3-7
.31
NLY 230 230.
1.0401NLY 2PS2 230.
1.0
356
CB
K 5
00
5
00.
50792
1.0451SEL 500 500.
-133.7
9
0.0
0
900.7
6
-887.99
5L
92
-54.2
1
125.34
51352
0.9732CBK 12T2 12.6
0.0
0
0.0
0
51353
0.9732CBK 12T3 12.6
50792
51352
51353
900.7
6
-887.99
1.0451
0.9732CBK 12T3 12.6
0.9732CBK 12T2 12.6
5L
92
-54.2
1
125.34
SEL 500 500.
50
78
2
1.0
224
CB
K 2
30
2
30.
0.00
0.00
43.07
-44.70
-42.18
44.71
50
78
2
1.0
224
CB
K 2
30
2
30.
0.00
0.00
43.07
-44.70
-42.18
44.71
-0.00
-0.00
43.10
-44.74
-42.21
44.75
80
64
1
0.9
894
SE
L 1
2T
1
12.6
80
30
6
0.9
894
SE
L 1
2T
4
12.6
80
30
5
0.9
894
SE
L 1
2T
3
12.6
80
64
1
80
30
6
80
30
5
0.9
894
SE
L 1
2T
3
12.6
0.9
894
SE
L 1
2T
4
12.6
0.9
894
SE
L 1
2T
1
12.6
-0.00
-0.00
43.10
-44.74
-42.21
44.75
80
30
4
0.9
895
SE
L 1
2T
2
12.6
50783
1.0418SEL 230 230.
-0.00
-0.00
-32.75
28.52
33.02
-28.52
80
30
4
50783
1.0418SEL 230 230.
-0.00
-0.00
-32.75
28.52
33.02
-28.52
0.9
895
SE
L 1
2T
2
12.6
0.00
0.00
-23.97
20.88
24.17
-20.88
0.00
-0.00
-23.73
20.67
23.93
-20.67
0.00
0.00
-23.97
0.00
-0.00
-23.73
20.67
23.93
-20.67
20.88
24.17
-20.88
0.00
-0.00
-32.78
28.55
33.05
-28.55
-247.5
4
248.7
7
2L293
5.7
1
-0.3
1
80640
1.0286AAL 2T3 230.
-135.8
2137.5
12
L2
94
6.1
9-7
.69
0.00
80640
-247.5
4
-135.8
2137.5
1
248.7
7
1.0286
2L
29
4
6.1
9-7
.69
AAL 2T3 230.
2L293
5.7
1
-0.3
1
-0.00
-32.78
28.55
33.05
-28.55
50
70
2
1.0
439
AC
K 5
00
5
00.
0.00
0.00
51
13
4
1.0
564
VA
S 5
00
5
00.
50
78
8
1.0
360
KC
L 2
30
2
30.
0.10
0.21
94.06
-93.5
1
2L295
-30.38
25.2
3
50
70
2
51
13
4
50
78
8
94.06
-93.5
1
1.0
360
2L295
-30.38
25.2
3
KC
L 2
30
2
30.
1.0
564
VA
S 5
00
5
00.
1.0
439
AC
K 5
00
5
00.
93.97
-93.4
3
2L299
-30.34
25.1
9
CBK
93.97
-93.4
3
0.10
0.21
SEL
2L299
-30.34
25.1
9
ACK
VAS
KCL
AAL
NLY
0.0
0
-133.7
9
0.0
0
0.0
0
50789
1.0286AAL 2T1 230. 114.8
2
-113.17
2L
29
4
-13.1
5
6.89
135.8
2-1
35.8
2
-6.4
36.4
7
50785
1.0418SEV 2T1 230.
50789
114.8
2
50785
135.8
2-1
35.8
2
-113.17
1.0286
2L
29
4
1.0418SEV 2T1 230.
-6.4
36.4
7-1
3.1
5
6.89
AAL 2T1 230.
-0.2
00.2
02
L2
21
-0.1
1-0
.81
51350
1.0414SEV 2T3 230. -0.2
00.2
02
L2
22
-16.9
115.9
9
-659.8
7
668.27
5L
91
-40.9
5
-9.83
51350
-0.2
0
-0.2
0
-659.8
7
668.27
0.2
0
0.2
0
1.0414
0.00
0.00
2L
22
2
5L
91
-40.9
5
-9.83
-16.9
115.9
9
SEV 2T3 230.
2L
22
1
-0.1
1-0
.81
142.59
-142.2
8
5L
96
-65.23
-152.7
9
SEV40146
1.0400BOUNDRYW 230.
150.8
5-1
50.7
62
L1
12
-16.2
316.2
3
50787
1.0135NTL 230 230.
142.59
40146
-142.2
8
50787
150.8
5-1
50.7
6
5L
96
1.0400
1.0135NTL 230 230.
2L
11
2-1
6.2
316.2
3
BOUNDRYW 230.
-65.23
-152.7
9
-6.77
0.6
2
2L
11
3-1
04.8
4
106.04
-6.77
0.6
2
2L
11
3
LA
NG
DO
N2
500.
54
15
8
1.0
432
-104.8
4
106.04
LA
NG
DO
N2
500.
54
15
8
1.0
432
-40.92 99.51
5L94798.54 -781.25
-40.92 99.51
5L94798.54 -781.25
Interface: AB-BC: Path-1
Total From MW Flow: 850.94 MW
Interface: BC-US: Path-3
Total From MW Flow: 1200.56 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -0.44 MW
54
23
2
CO
LE
MA
N7
138.
1.0
284
54
23
2
CO
LE
MA
N7
138.
1.0
284
50
77
6
NT
L 1
38
1
38.
1.0
386
50
77
6
NT
L 1
38
1
38.
1.0
386
49.35
-8.25
-48.55
7.98
49.35
-8.25
-48.55
7.98
50
83
0
BC
K 2
74P
138.
1.0
090
50
83
0
BC
K 2
74P
138.
1.0
090
54
32
9
PO
CA
TE
R7
138.
1.0
426
54
32
9
PO
CA
TE
R7
138.
1.0
426
3.05
-1.83
-3.05
-1.17
3.05
-1.83
-3.05
-1.17
13hs_case1b_P1_08505
07
69
KC
L 1
3G
1
13.8
0.9
987
0.001
-43.03
50
76
9
KC
L 1
3G
1
13.8
0.9
987
0.001
-43.03
50
77
0
KC
L 1
3G
2
13.8
1.0
355
2
50
77
0
KC
L 1
3G
2
13.8
1.0
355
2
50
77
1
KC
L 1
3G
3
13.8
1.0
355
3
50
77
1
KC
L 1
3G
3
13.8
1.0
355
3
50
77
2
KC
L 1
3G
4
13.8
1.0
355
4
50
77
2
KC
L 1
3G
4
13.8
1.0
355
4
50766
SEV 13G1 13.8 1.0413
1
50766
SEV 13G1 13.8 1.0413
1
50767
SEV 13G2 13.8 1.0413
2
50767
SEV 13G2 13.8 1.0413
2
50768
SEV 13G3 13.8 1.0409
3
50768
SEV 13G3 13.8 1.0409
3
51036
SEV 13G4 13.8 1.0332
0.0
04
-16.7
051036
SEV 13G4 13.8 1.0332
0.0
04
-16.7
0
50786
INV 230 230. 1.0613
50786
INV 230 230. 1.0613
34.55
-49.89
-34.1
3
27.6
1
2L
25
8
34.55
-49.89
-34.1
3
27.6
1
2L
25
8
Report No. T&S Planning – 2013-058 Page 20
Not to be reproduced without the permission of BC Hydro
50
79
1
1.0
058
CB
K 5
00
5
00.
50822
1.0397NLY 2PS2 230.
50784
1.0343NLY 230 230.
-55.5
255.5
6
16.0
6-1
4.8
2
50
79
1
50822
50784
-55.5
255.5
6
1.0343
16.0
6-1
4.8
2
NLY 230 230.
1.0397NLY 2PS2 230.
1.0
058
CB
K 5
00
5
00.
50792
1.0426SEL 500 500.
-133.1
6
0.0
0
1114.1
6
-1093.87
5L
92
100.8
2
74.59
51352
0.9460CBK 12T2 12.6
0.0
0
0.0
0
51353
0.9461CBK 12T3 12.6
50792
51352
51353
1114.1
6
-1093.87
1.0426
0.9461CBK 12T3 12.6
0.9460CBK 12T2 12.6
5L
92
100.8
2
74.59
SEL 500 500.
50
78
2
0.9
937
CB
K 2
30
2
30.
0.00
0.00
43.45
-24.63
-42.84
24.64
50
78
2
0.9
937
CB
K 2
30
2
30.
0.00
0.00
43.45
-24.63
-42.84
24.64
-0.00
0.00
43.48
-24.65
-42.87
24.66
80
64
1
0.9
868
SE
L 1
2T
1
12.6
80
30
6
0.9
867
SE
L 1
2T
4
12.6
80
30
5
0.9
868
SE
L 1
2T
3
12.6
80
64
1
80
30
6
80
30
5
0.9
868
SE
L 1
2T
3
12.6
0.9
867
SE
L 1
2T
4
12.6
0.9
868
SE
L 1
2T
1
12.6
-0.00
0.00
43.48
-24.65
-42.87
24.66
80
30
4
0.9
869
SE
L 1
2T
2
12.6
50783
1.0390SEL 230 230.
-0.00
-0.00
-34.75
103.40
36.47
-103.38
80
30
4
50783
1.0390SEL 230 230.
-0.00
-0.00
-34.75
103.40
36.47
-103.38
0.9
869
SE
L 1
2T
2
12.6
-0.00
-0.00
-25.44
75.70
26.69
-75.68
0.00
-0.00
-25.19
74.95
26.44
-74.93
-0.00
-0.00
-25.44
0.00
-0.00
-25.19
74.95
26.44
-74.93
75.70
26.69
-75.68
0.00
0.00
-34.78
103.51
36.51
-103.49
-195.7
3
196.5
0
2L293
-3.0
6
5.3
1
80640
1.0114AAL 2T3 230.
-178.7
4181.7
42
L2
94
-5.9
613.2
8
0.00
80640
-195.7
3
-178.7
4181.7
4
196.5
0
1.0114
2L
29
4
-5.9
613.2
8
AAL 2T3 230.
2L293
-3.0
6
5.3
1
0.00
-34.78
103.51
36.51
-103.49
50
70
2
1.0
706
AC
K 5
00
5
00.
573.12
0.00
51
13
4
1.0
639
VA
S 5
00
5
00.
50
78
8
1.0
360
KC
L 2
30
2
30.
0.10
0.21
137.70
-136.5
8
2L295
-27.93
26.7
5
50
70
2
51
13
4
50
78
8
137.70
-136.5
8
1.0
360
2L295
-27.93
26.7
5
KC
L 2
30
2
30.
1.0
639
VA
S 5
00
5
00.
1.0
706
AC
K 5
00
5
00.
137.58
-136.4
6
2L299
-27.90
26.7
0
CBK
137.58
-136.4
6
0.10
0.21
SEL
2L299
-27.90
26.7
0
ACK
VAS
KCL
AAL
NLY
0.0
0
-133.1
6
0.0
0
0.0
0
50789
1.0114AAL 2T1 230. 157.7
3
-154.51
2L
29
4
-0.9
3
5.89
178.7
3-1
78.7
3
5.7
7-5
.70
50785
1.0389SEV 2T1 230.
50789
157.7
3
50785
178.7
3-1
78.7
3
-154.51
1.0114
2L
29
4
1.0389SEV 2T1 230.
5.7
7-5
.70
-0.9
3
5.89
AAL 2T1 230.
82.6
9-8
2.6
72
L2
21
-14.5
113.7
4
51350
1.0390SEV 2T3 230. -0.2
00.2
02
L2
22
-0.0
9-0
.83
-613.3
3
620.43
5L
91
-159.5
0
90.08
51350
82.6
9
-0.2
0
-613.3
3
620.43
0.2
0
-82.6
7
1.0390
573.12
0.00
2L
22
2
5L
91
-159.5
0
90.08
-0.0
9-0
.83
SEV 2T3 230.
2L
22
1
-14.5
113.7
4
143.75
-143.3
5
5L
96
-17.19
-200.5
4
SEV40146
1.0400BOUNDRYW 230.
55.5
2-5
5.5
12
L1
12
-16.0
515.4
0
50787
0.9784NTL 230 230.
143.75
40146
-143.3
5
50787
55.5
2-5
5.5
1
5L
96
1.0400
0.9784NTL 230 230.
2L
11
2-1
6.0
515.4
0
BOUNDRYW 230.
-17.19
-200.5
4
2.13
-6.7
7
2L
11
3-1
05.5
7
106.86
2.13
-6.7
7
2L
11
3
LA
NG
DO
N2
500.
54
15
8
1.0
271
-105.5
7
106.86
LA
NG
DO
N2
500.
54
15
8
1.0
271
11.25 252.81
5L941044.57 -1013.05
11.25 252.81
5L941044.57 -1013.05
Interface: AB-BC: Path-1
Total From MW Flow: 1097.98 MW
Interface: BC-US: Path-3
Total From MW Flow: 1000.48 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -0.52 MW
54
23
2
CO
LE
MA
N7
138.
1.0
206
54
23
2
CO
LE
MA
N7
138.
1.0
206
50
77
6
NT
L 1
38
1
38.
1.0
280
50
77
6
NT
L 1
38
1
38.
1.0
280
48.76
-11.76
-47.94
11.56
48.76
-11.76
-47.94
11.56
50
83
0
BC
K 2
74P
138.
0.9
957
50
83
0
BC
K 2
74P
138.
0.9
957
54
32
9
PO
CA
TE
R7
138.
1.0
417
54
32
9
PO
CA
TE
R7
138.
1.0
417
4.65
-1.35
-4.64
-0.44
4.65
-1.35
-4.64
-0.44
13hs_case2a_P1_11005
07
69
KC
L 1
3G
1
13.8
1.0
111
130.001
-25.61
50
76
9
KC
L 1
3G
1
13.8
1.0
111
130.001
-25.61
50
77
0
KC
L 1
3G
2
13.8
1.0
355
2
50
77
0
KC
L 1
3G
2
13.8
1.0
355
2
50
77
1
KC
L 1
3G
3
13.8
1.0
355
3
50
77
1
KC
L 1
3G
3
13.8
1.0
355
3
50
77
2
KC
L 1
3G
4
13.8
1.0
355
4
50
77
2
KC
L 1
3G
4
13.8
1.0
355
4
50766
SEV 13G1 13.8 1.0327
83.0
01
-10.5
4
50766
SEV 13G1 13.8 1.0327
83.0
01
-10.5
4
50767
SEV 13G2 13.8 1.0384
2
50767
SEV 13G2 13.8 1.0384
2
50768
SEV 13G3 13.8 1.0386
3
50768
SEV 13G3 13.8 1.0386
3
51036
SEV 13G4 13.8 1.0386
4
51036
SEV 13G4 13.8 1.0386
4
50786
INV 230 230. 1.0344
50786
INV 230 230. 1.0344
34.23
-49.77
-33.7
7
29.0
1
2L
25
8
34.23
-49.77
-33.7
7
29.0
1
2L
25
8
Report No. T&S Planning – 2013-058 Page 21
Not to be reproduced without the permission of BC Hydro
50
79
1
0.9
869
CB
K 5
00
5
00.
50822
1.0394NLY 2PS2 230.
50784
1.0282NLY 230 230.
-250.2
8251.0
1
47.2
9-2
1.8
7
50
79
1
50822
50784
-250.2
8251.0
1
1.0282
47.2
9-2
1.8
7
NLY 230 230.
1.0394NLY 2PS2 230.
0.9
869
CB
K 5
00
5
00.
50792
1.0422SEL 500 500.
0.0
0
0.0
0
1208.4
2
-1183.81
5L
92
201.7
0
33.37
51352
0.9271CBK 12T2 12.6
0.0
0
0.0
0
51353
0.9272CBK 12T3 12.6
50792
51352
51353
1208.4
2
-1183.81
1.0422
0.9272CBK 12T3 12.6
0.9271CBK 12T2 12.6
5L
92
201.7
0
33.37
SEL 500 500.
50
78
2
0.9
740
CB
K 2
30
2
30.
-0.00
-0.00
37.38
-18.09
-36.94
18.10
50
78
2
0.9
740
CB
K 2
30
2
30.
-0.00
-0.00
37.38
-18.09
-36.94
18.10
-0.00
-0.00
37.41
-18.11
-36.97
18.11
80
64
1
0.9
847
SE
L 1
2T
1
12.6
80
30
6
0.9
847
SE
L 1
2T
4
12.6
80
30
5
0.9
847
SE
L 1
2T
3
12.6
80
64
1
80
30
6
80
30
5
0.9
847
SE
L 1
2T
3
12.6
0.9
847
SE
L 1
2T
4
12.6
0.9
847
SE
L 1
2T
1
12.6
-0.00
-0.00
37.41
-18.11
-36.97
18.11
80
30
4
0.9
850
SE
L 1
2T
2
12.6
50783
1.0370SEL 230 230.
0.00
-0.00
-42.68
304.44
56.40
-304.24
80
30
4
50783
1.0370SEL 230 230.
0.00
-0.00
-42.68
304.44
56.40
-304.24
0.9
850
SE
L 1
2T
2
12.6
0.14
0.00
-31.39
222.86
41.29
-222.72
-0.00
-0.00
-30.94
220.67
40.88
-220.52
0.14
0.00
-31.39
-0.00
-0.00
-30.94
220.67
40.88
-220.52
222.86
41.29
-222.72
-0.00
0.00
-42.72
304.75
56.46
-304.55
-379.4
8
382.4
2
2L293
2.8
3
14.4
7
80640
0.9979AAL 2T3 230.
-193.1
8196.7
82
L2
94
-13.0
524.5
6
-0.00
80640
-379.4
8
-193.1
8196.7
8
382.4
2
0.9979
2L
29
4-1
3.0
524.5
6
AAL 2T3 230.
2L293
2.8
3
14.4
7
0.00
-42.72
304.75
56.46
-304.55
50
70
2
1.0
600
AC
K 5
00
5
00.
280.90
0.00
51
13
4
1.0
623
VA
S 5
00
5
00.
50
78
8
1.0
360
KC
L 2
30
2
30.
0.10
0.21
278.48
-274.0
0
2L295
-31.49
53.4
8
50
70
2
51
13
4
50
78
8
278.48
-274.0
0
1.0
360
2L295
-31.49
53.4
8
KC
L 2
30
2
30.
1.0
623
VA
S 5
00
5
00.
1.0
600
AC
K 5
00
5
00.
278.23
-273.7
6
2L299
-31.44
53.3
9
CBK
278.23
-273.7
6
0.10
0.21
SEL
2L299
-31.44
53.3
9
ACK
VAS
KCL
AAL
NLY
0.0
0
0.0
0
0.0
0
0.0
0
50789
0.9979AAL 2T1 230. 172.1
6
-168.21
2L
29
4
6.2
2
4.20
193.1
8-1
93.1
8
12.9
9-1
2.9
2
50785
1.0381SEV 2T1 230.
50789
172.1
6
50785
193.1
8-1
93.1
8
-168.21
0.9979
2L
29
4
1.0381SEV 2T1 230.
12.9
9-1
2.9
26.2
2
4.20
AAL 2T1 230.
289.2
4-2
89.0
42
L2
21
16.9
4-1
6.0
9
51350
1.0383SEV 2T3 230. 289.2
6-2
89.0
52
L2
22
29.8
4-2
8.9
8
-300.3
4
302.06
5L
91
-182.0
1
37.22
51350
289.2
4
289.2
6
-300.3
4
302.06
-289.0
5
-289.0
4
1.0383
280.90
0.00
2L
22
2
5L
91
-182.0
1
37.22
29.8
4-2
8.9
8
SEV 2T3 230.
2L
22
1
16.9
4-1
6.0
9
-143.51
143.9
6
5L
96
-2.00
-214.7
2
SEV40146
1.0400BOUNDRYW 230.
250.2
8-2
50.0
22
L1
12
-47.3
048.7
0
50787
0.9422NTL 230 230.
-143.51
40146
143.9
6
50787
250.2
8-2
50.0
2
5L
96
1.0400
0.9422NTL 230 230.
2L
11
2-4
7.3
048.7
0
BOUNDRYW 230.
-2.00
-214.7
2
23.95
-26.7
9
2L
11
3-1
05.8
7
107.32
23.95
-26.7
9
2L
11
3
LA
NG
DO
N2
500.
54
15
8
1.0
177
-105.8
7
107.32
LA
NG
DO
N2
500.
54
15
8
1.0
177
40.60 340.79
5L941147.61 -1107.98
40.60 340.79
5L941147.61 -1107.98
Interface: AB-BC: Path-1
Total From MW Flow: 1201.09 MW
Interface: BC-US: Path-3
Total From MW Flow: 1032.64 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -0.35 MW
54
23
2
CO
LE
MA
N7
138.
1.0
262
54
23
2
CO
LE
MA
N7
138.
1.0
262
50
77
6
NT
L 1
38
1
38.
1.0
326
50
77
6
NT
L 1
38
1
38.
1.0
326
48.04
-12.72
-47.24
12.45
48.04
-12.72
-47.24
12.45
50
83
0
BC
K 2
74P
138.
0.9
995
50
83
0
BC
K 2
74P
138.
0.9
995
54
32
9
PO
CA
TE
R7
138.
1.0
417
54
32
9
PO
CA
TE
R7
138.
1.0
417
5.44
-0.95
-5.43
-0.11
5.44
-0.95
-5.43
-0.11
13hs_case3_P1_12005
07
69
KC
L 1
3G
1
13.8
1.0
343
142.501
2.56
50
76
9
KC
L 1
3G
1
13.8
1.0
343
142.501
2.56
50
77
0
KC
L 1
3G
2
13.8
1.0
343
142.502
2.56
50
77
0
KC
L 1
3G
2
13.8
1.0
343
142.502
2.56
50
77
1
KC
L 1
3G
3
13.8
1.0
341
142.503
2.56
50
77
1
KC
L 1
3G
3
13.8
1.0
341
142.503
2.56
50
77
2
KC
L 1
3G
4
13.8
1.0
341
142.504
2.56
50
77
2
KC
L 1
3G
4
13.8
1.0
341
142.504
2.56
50766
SEV 13G1 13.8 1.0500
145.0
01
23.7
1
50766
SEV 13G1 13.8 1.0500
145.0
01
23.7
1
50767
SEV 13G2 13.8 1.0500
145.0
02
21.4
3
50767
SEV 13G2 13.8 1.0500
145.0
02
21.4
3
50768
SEV 13G3 13.8 1.0500
145.0
03
23.1
1
50768
SEV 13G3 13.8 1.0500
145.0
03
23.1
1
51036
SEV 13G4 13.8 1.0500
145.0
04
27.8
451036
SEV 13G4 13.8 1.0500
145.0
04
27.8
4
50786
INV 230 230. 1.0233
50786
INV 230 230. 1.0233
34.95
-55.72
-34.3
8
36.5
3
2L
25
8
34.95
-55.72
-34.3
8
36.5
3
2L
25
8
Report No. T&S Planning – 2013-058 Page 22
Not to be reproduced without the permission of BC Hydro
50
79
1
0.9
878
CB
K 5
00
5
00.
50822
1.0396NLY 2PS2 230.
50784
1.0339NLY 230 230.
-51.0
651.0
9
16.7
1-1
5.6
4
50
79
1
50822
50784
-51.0
651.0
9
1.0339
16.7
1-1
5.6
4
NLY 230 230.
1.0396NLY 2PS2 230.
0.9
878
CB
K 5
00
5
00.
50792
1.0440SEL 500 500.
0.0
0
0.0
0
1206.7
3
-1182.24
5L
92
204.8
2
28.26
51352
0.9274CBK 12T2 12.6
0.0
0
0.0
0
51353
0.9274CBK 12T3 12.6
50792
51352
51353
1206.7
3
-1182.24
1.0440
0.9274CBK 12T3 12.6
0.9274CBK 12T2 12.6
5L
92
204.8
2
28.26
SEL 500 500.
50
78
2
0.9
744
CB
K 2
30
2
30.
0.00
0.00
35.27
-17.55
-34.87
17.55
50
78
2
0.9
744
CB
K 2
30
2
30.
0.00
0.00
35.27
-17.55
-34.87
17.55
0.00
0.00
35.29
-17.56
-34.90
17.56
80
64
1
0.9
883
SE
L 1
2T
1
12.6
80
30
6
0.9
883
SE
L 1
2T
4
12.6
80
30
5
0.9
884
SE
L 1
2T
3
12.6
80
64
1
80
30
6
80
30
5
0.9
884
SE
L 1
2T
3
12.6
0.9
883
SE
L 1
2T
4
12.6
0.9
883
SE
L 1
2T
1
12.6
0.00
0.00
35.29
-17.56
-34.90
17.56
80
30
4
0.9
884
SE
L 1
2T
2
12.6
50783
1.0406SEL 230 230.
0.00
-0.00
-33.64
130.62
36.27
-130.59
80
30
4
50783
1.0406SEL 230 230.
0.00
-0.00
-33.64
130.62
36.27
-130.59
0.9
884
SE
L 1
2T
2
12.6
0.00
-0.00
-24.63
95.62
26.54
-95.60
0.00
-0.00
-24.38
94.68
26.29
-94.65
0.00
-0.00
-24.63
0.00
-0.00
-24.38
94.68
26.29
-94.65
95.62
26.54
-95.60
-0.00
-0.00
-33.68
130.76
36.30
-130.72
-205.9
6
206.8
2
2L293
-15.2
6
18.1
1
80640
1.0016AAL 2T3 230.
-193.8
0197.4
12
L2
94
-16.6
228.0
4
-0.00
80640
-205.9
6
-193.8
0197.4
1
206.8
2
1.0016
2L
29
4-1
6.6
228.0
4
AAL 2T3 230.
2L293
-15.2
6
18.1
1
-0.00
-33.68
130.76
36.30
-130.72
50
70
2
1.0
630
AC
K 5
00
5
00.
282.50
0.00
51
13
4
1.0
653
VA
S 5
00
5
00.
50
78
8
1.0
360
KC
L 2
30
2
30.
0.10
0.21
144.08
-142.8
5
2L295
-32.40
31.9
9
50
70
2
51
13
4
50
78
8
144.08
-142.8
5
1.0
360
2L295
-32.40
31.9
9
KC
L 2
30
2
30.
1.0
653
VA
S 5
00
5
00.
1.0
630
AC
K 5
00
5
00.
143.95
-142.7
2
2L299
-32.35
31.9
4
CBK
143.95
-142.7
2
0.10
0.21
SEL
2L299
-32.35
31.9
4
ACK
VAS
KCL
AAL
NLY
0.0
0
0.0
0
0.0
0
0.0
0
50789
1.0015AAL 2T1 230. 172.7
9
-168.82
2L
29
4
9.8
6
0.59
193.8
0-1
93.8
0
16.6
4-1
6.5
7
50785
1.0415SEV 2T1 230.
50789
172.7
9
50785
193.8
0-1
93.8
0
-168.82
1.0015
2L
29
4
1.0415SEV 2T1 230.
16.6
4-1
6.5
79.8
6
0.59
AAL 2T1 230.
169.6
1-1
69.5
42
L2
21
18.5
1-1
8.8
2
51350
1.0406SEV 2T3 230. -0.2
00.2
02
L2
22
-0.1
0-0
.83
-595.9
6
602.65
5L
91
-130.8
0
55.47
51350
169.6
1
-0.2
0
-595.9
6
602.65
0.2
0
-169.5
4
1.0406
282.50
0.00
2L
22
2
5L
91
-130.8
0
55.47
-0.1
0-0
.83
SEV 2T3 230.
2L
22
1
18.5
1-1
8.8
2
159.68
-159.2
1
5L
96
-18.01
-199.4
6
SEV40146
1.0400BOUNDRYW 230.
51.0
6-5
1.0
52
L1
12
-16.7
016.0
3
50787
0.9464NTL 230 230.
159.68
40146
-159.2
1
50787
51.0
6-5
1.0
5
5L
96
1.0400
0.9464NTL 230 230.
2L
11
2-1
6.7
016.0
3
BOUNDRYW 230.
-18.01
-199.4
6
18.95
-22.1
0
2L
11
3-1
05.7
5
107.16
18.95
-22.1
0
2L
11
3
LA
NG
DO
N2
500.
54
15
8
1.0
179
-105.7
5
107.16
LA
NG
DO
N2
500.
54
15
8
1.0
179
41.46 338.36
5L941147.13 -1107.60
41.46 338.36
5L941147.13 -1107.60
Interface: AB-BC: Path-1
Total From MW Flow: 1200.49 MW
Interface: BC-US: Path-3
Total From MW Flow: 998.95 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: 0.47 MW
54
23
2
CO
LE
MA
N7
138.
1.0
265
54
23
2
CO
LE
MA
N7
138.
1.0
265
50
77
6
NT
L 1
38
1
38.
1.0
355
50
77
6
NT
L 1
38
1
38.
1.0
355
47.89
-9.22
-47.13
8.87
47.89
-9.22
-47.13
8.87
50
83
0
BC
K 2
74P
138.
1.0
025
50
83
0
BC
K 2
74P
138.
1.0
025
54
32
9
PO
CA
TE
R7
138.
1.0
426
54
32
9
PO
CA
TE
R7
138.
1.0
426
5.47
-0.93
-5.46
-0.12
5.47
-0.93
-5.46
-0.12
13hs_case3a_P1_12005
07
69
KC
L 1
3G
1
13.8
1.0
356
1
50
76
9
KC
L 1
3G
1
13.8
1.0
356
1
50
77
0
KC
L 1
3G
2
13.8
1.0
356
2
50
77
0
KC
L 1
3G
2
13.8
1.0
356
2
50
77
1
KC
L 1
3G
3
13.8
1.0
171
75.003
-21.03
50
77
1
KC
L 1
3G
3
13.8
1.0
171
75.003
-21.03
50
77
2
KC
L 1
3G
4
13.8
1.0
172
75.004
-21.03
50
77
2
KC
L 1
3G
4
13.8
1.0
172
75.004
-21.03
50766
SEV 13G1 13.8 1.0500
85.0
01
15.6
2
50766
SEV 13G1 13.8 1.0500
85.0
01
15.6
2
50767
SEV 13G2 13.8 1.0500
85.0
02
12.6
8
50767
SEV 13G2 13.8 1.0500
85.0
02
12.6
8
50768
SEV 13G3 13.8 1.0402
3
50768
SEV 13G3 13.8 1.0402
3
51036
SEV 13G4 13.8 1.0402
4
51036
SEV 13G4 13.8 1.0402
4
50786
INV 230 230. 1.0212
50786
INV 230 230. 1.0212
34.55
-53.68
-34.0
1
34.2
7
2L
25
8
34.55
-53.68
-34.0
1
34.2
7
2L
25
8
Report No. T&S Planning – 2013-058 Page 23
Not to be reproduced without the permission of BC Hydro
50
79
1
1.0
201
CB
K 5
00 5
00.
50822
1.0383NLY 2PS2230.
50784
1.0330NLY 230 230.
250.8
3-2
50.2
1
18.5
02.9
5
50
79
1
50822
50784
250.8
3-2
50.2
1
1.0330
18.5
02.9
5
NLY 230 230.
1.0383NLY 2PS2230.
1.0
201
CB
K 5
00 5
00.
50792
1.0373SEL 500 500.
0.0
0
0.0
0
933.7
5
-919.71
5L
92
-12.9
3
102.97
51352
0.9543CBK 12T212.6
0.0
0
0.0
0
51353
0.9543CBK 12T312.6
50792
51352
51353
933.7
5
-919.71
1.0373
0.9543CBK 12T312.6
0.9543CBK 12T212.6
5L
92
-12.9
3
102.97
SEL 500 500.
50
78
2
1.0
032
CB
K 2
30 2
30.
0.00
-0.00
25.62
-45.05
-24.97
45.05
50
78
2
1.0
032
CB
K 2
30 2
30.
0.00
-0.00
25.62
-45.05
-24.97
45.05
-0.00
-0.00
25.63
-45.08
-24.99
45.09
80
64
1
0.9
789
SE
L 1
2T
112.6
80
30
6
0.9
788
SE
L 1
2T
412.6
80
30
5
0.9
789
SE
L 1
2T
312.6
80
64
1
80
30
6
80
30
5
0.9
789
SE
L 1
2T
312.6
0.9
788
SE
L 1
2T
412.6
0.9
789
SE
L 1
2T
112.6
-0.00
-0.00
25.63
-45.08
-24.99
45.09
80
30
4
0.9
790
SE
L 1
2T
212.6
50783
1.0307SEL 230 230.
0.00
0.00
-43.07
485.55
77.99
-485.05
80
30
4
50783
1.0307SEL 230 230.
0.00
0.00
-43.07
485.55
77.99
-485.05
0.9
790
SE
L 1
2T
212.6
0.00
0.00
-31.51
355.45
57.07
-355.08
-0.00
0.00
-31.23
351.94
56.54
-351.58
0.00
0.00
-31.51
-0.00
0.00
-31.23
351.94
56.54
-351.58
355.45
57.07
-355.08
-0.00
-0.00
-43.12
486.05
78.08
-485.55
170.4
3
-169.8
4
2L293
-8.4
9
9.4
9
80640
1.0071AAL 2T3 230.
-231.3
4236.4
22
L2
94
4.3
416.6
6
-0.00
80640
170.4
3
-231.3
4236.4
2
-169.8
4
1.0071
2L
29
4
4.3
416.6
6
AAL 2T3 230.
2L293
-8.4
9
9.4
9
-0.00
-43.12
486.05
78.08
-485.55
50
70
2
1.0
547
AC
K 5
00 5
00.
51
13
4
1.0
480
VA
S 5
00 5
00.
50
78
8
1.0
360
KC
L 2
30 2
30.
0.10
0.21
240.29
-236.9
8
2L295
-14.85
28.8
4
50
70
2
51
13
4
50
78
8
240.29
-236.9
8
1.0
360
2L295
-14.85
28.8
4
KC
L 2
30 2
30.
1.0
480
VA
S 5
00 5
00.
1.0
547
AC
K 5
00 5
00.
240.07
-236.7
7
2L299
-14.81
28.7
7
CBK
240.07
-236.7
7
0.10
0.21
SEL
2L299
-14.81
28.7
7
ACK
VAS
KCL
AAL
NLY
50789
1.0071AAL 2T1 230. 197.9
6
-192.85
2L
29
4
-16.2
3
33.70
231.3
4-2
31.3
4
-4.3
44.3
4
50785
1.0311SEV 2T1 230.
50789
197.9
6
50785
231.3
4-2
31.3
4
-192.85
1.0071
2L
29
4
1.0311SEV 2T1 230.
-4.3
44.3
4-1
6.2
3
33.70
AAL 2T1 230.
388.7
7-3
88.4
02
L2
21
-25.5
127.8
4
51350
1.0314SEV 2T3 230. 383.8
4-3
83.4
82
L2
22
-11.7
514.0
0
188.5
5
-187.78
5L
91
-220.1
9
63.63
51350
388.7
7
383.8
4
188.5
5
-187.78
-383.4
8
-388.4
0
1.0314
2L
22
2
5L
91
-220.1
9
63.63
-11.7
514.0
0
SEV 2T3 230.
2L
22
1
-25.5
127.8
4
-550.53
554.9
6
5L
96
11.78
-36.5
6
SEV40146
1.0400BOUNDRYW230.
-250.8
3251.0
82
L1
12
-18.4
919.8
4
50787
0.9881NTL 230 230.
-550.53
40146
554.9
6
50787
-250.8
3251.0
8
5L
96
1.0400
0.9881NTL 230 230.
2L
11
2-1
8.4
919.8
4
BOUNDRYW230.
11.78
-36.5
6
1.10
-4.3
6
2L
11
3-1
16.4
8
118.02
1.10
-4.3
6
2L
11
3
LA
NG
DO
N2500.
54
15
8
1.0
378
-116.4
8
118.02
LA
NG
DO
N2500.
54
15
8
1.0
378
Interface: AB-BC: Path-1
Total From MW Flow: 868.50 MW
Interface: BC-US: Path-3
Total From MW Flow: -850.84 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: 0.11 MW
54
23
2
CO
LE
MA
N9138.
1.0
219
54
23
2
CO
LE
MA
N9138.
1.0
219
50
77
6
NT
L 1
38 1
38.
1.0
235
50
77
6
NT
L 1
38 1
38.
1.0
235
50
83
0
BC
K 2
74P
138.
0.9
821
50
83
0
BC
K 2
74P
138.
0.9
821
54
32
9
PO
CA
TE
R7138.
1.0
404
54
32
9
PO
CA
TE
R7138.
1.0
404
1L2741L274
13hw2ae_case1_P1_08695
07
69
KC
L 1
3G
113.8
1.0
395
123.491
7.26
50
76
9
KC
L 1
3G
113.8
1.0
395
123.491
7.26
50
77
0
KC
L 1
3G
213.8
1.0
395
123.492
7.26
50
77
0
KC
L 1
3G
213.8
1.0
395
123.492
7.26
50
77
1
KC
L 1
3G
313.8
1.0
394
123.493
7.26
50
77
1
KC
L 1
3G
313.8
1.0
394
123.493
7.26
50
77
2
KC
L 1
3G
413.8
1.0
394
123.494
7.26
50
77
2
KC
L 1
3G
413.8
1.0
394
123.494
7.26
50766
SEV 13G113.8 1.0351
195.0
01
12.7
3
50766
SEV 13G113.8 1.0351
195.0
01
12.7
3
50767
SEV 13G213.8 1.0314
195.0
02
13.4
7
50767
SEV 13G213.8 1.0314
195.0
02
13.4
7
50768
SEV 13G313.8 1.0353
195.0
03
12.6
2
50768
SEV 13G313.8 1.0353
195.0
03
12.6
2
51036
SEV 13G413.8 1.0352
190.0
04
12.9
751036
SEV 13G413.8 1.0352
190.0
04
12.9
7
50786
INV 230 230. 1.0282
50786
INV 230 230. 1.0282
84.38
-40.58
-83.0
3
25.9
3
2L
25
8
84.38
-40.58
-83.0
3
25.9
3
2L
25
8
-38.36
14.42
38.93
-15.19
1L275 -38.36
14.42
38.93
-15.19
1L275
0.0
0
0.0
0
-810.37
141.65
829.57
-53.00
5L94 -810.37
141.65
829.57
-53.00
5L94
0.0
0
0.0
0
Report No. T&S Planning – 2013-058 Page 24
Not to be reproduced without the permission of BC Hydro
50
79
1
1.0
247
CB
K 5
00 5
00.
50822
1.0387NLY 2PS2230.
50784
1.0378NLY 230 230.
251.2
4-2
50.5
3
7.4
117.5
3
50
79
1
50822
50784
251.2
4-2
50.5
3
1.0378
7.4
117.5
3
NLY 230 230.
1.0387NLY 2PS2230.
1.0
247
CB
K 5
00 5
00.
50792
1.0403SEL 500 500.
0.0
0
-132.5
6
941.3
3
-927.17
5L
92
-20.0
7
111.27
51352
0.9598CBK 12T212.6
0.0
0
0.0
0
51353
0.9599CBK 12T312.6
50792
51352
51353
941.3
3
-927.17
1.0403
0.9599CBK 12T312.6
0.9598CBK 12T212.6
5L
92
-20.0
7
111.27
SEL 500 500.
50
78
2
1.0
089
CB
K 2
30 2
30.
-0.00
0.00
30.79
-57.62
-29.78
57.63
50
78
2
1.0
089
CB
K 2
30 2
30.
-0.00
0.00
30.79
-57.62
-29.78
57.63
0.00
0.00
30.82
-57.66
-29.80
57.67
80
64
1
0.9
860
SE
L 1
2T
112.6
80
30
6
0.9
860
SE
L 1
2T
412.6
80
30
5
0.9
860
SE
L 1
2T
312.6
80
64
1
80
30
6
80
30
5
0.9
860
SE
L 1
2T
312.6
0.9
860
SE
L 1
2T
412.6
0.9
860
SE
L 1
2T
112.6
0.00
0.00
30.82
-57.66
-29.80
57.67
80
30
4
0.9
861
SE
L 1
2T
212.6
50783
1.0380SEL 230 230.
0.00
-0.00
-25.77
139.34
28.68
-139.30
80
30
4
50783
1.0380SEL 230 230.
0.00
-0.00
-25.77
139.34
28.68
-139.30
0.9
861
SE
L 1
2T
212.6
-0.00
-0.00
-18.86
102.01
20.99
-101.98
-0.00
-0.00
-18.68
101.00
20.79
-100.97
-0.00
-0.00
-18.86
-0.00
-0.00
-18.68
101.00
20.79
-100.97
102.01
20.99
-101.98
-0.00
-0.00
-25.80
139.49
28.72
-139.44
188.0
2
-187.3
0
2L293
-27.7
6
29.6
5
80640
1.0156AAL 2T3 230.
-204.0
0207.8
82
L2
94
1.8
211.1
8
-0.00
80640
188.0
2
-204.0
0207.8
8
-187.3
0
1.0156
2L
29
4
1.8
211.1
8
AAL 2T3 230.
2L293
-27.7
6
29.6
5
-0.00
-25.80
139.49
28.72
-139.44
50
70
2
1.0
620
AC
K 5
00 5
00.
51
13
4
1.0
544
VA
S 5
00 5
00.
50
78
8
1.0
360
KC
L 2
30 2
30.
0.10
0.21
80.63
-80.2
4
2L295
-19.74
13.5
3
50
70
2
51
13
4
50
78
8
80.63
-80.2
4
1.0
360
2L295
-19.74
13.5
3
KC
L 2
30 2
30.
1.0
544
VA
S 5
00 5
00.
1.0
620
AC
K 5
00 5
00.
80.55
-80.1
7
2L299
-19.72
13.4
9
CBK
80.55
-80.1
7
0.10
0.21
SEL
2L299
-19.72
13.4
9
ACK
VAS
KCL
AAL
NLY
50789
1.0156AAL 2T1 230. 170.6
3
-166.90
2L
29
4
-13.6
5
21.70
204.0
0-2
04.0
0
-1.8
21.8
2
50785
1.0379SEV 2T1 230.
50789
170.6
3
50785
204.0
0-2
04.0
0
-166.90
1.0156
2L
29
4
1.0379SEV 2T1 230.
-1.8
21.8
2-1
3.6
5
21.70
AAL 2T1 230.
-0.2
00.2
02
L2
21
-4.2
83.3
8
51350
1.0380SEV 2T3 230. -0.2
00.2
02
L2
22
-0.1
0-0
.82
-467.3
5
471.50
5L
91
-166.5
9
56.47
51350
-0.2
0
-0.2
0
-467.3
5
471.50
0.2
0
0.2
0
1.0380
2L
22
2
5L
91
-166.5
9
56.47
-0.1
0-0
.82
SEV 2T3 230.
2L
22
1
-4.2
83.3
8
-7.67
7.7
4
5L
96
-42.33
-45.0
9
SEV40146
1.0400BOUNDRYW230.
-251.2
4251.4
92
L1
12
-7.4
18.7
6
50787
0.9929NTL 230 230.
-7.67
40146
7.7
4
50787
-251.2
4251.4
9
5L
96
1.0400
0.9929NTL 230 230.
2L
11
2
-7.4
18.7
6
BOUNDRYW230.
-42.33
-45.0
9
2.26
-5.8
6
2L
11
3-1
15.9
1
117.42
2.26
-5.8
6
2L
11
3
LA
NG
DO
N2500.
54
15
8
1.0
394
-115.9
1
117.42
LA
NG
DO
N2500.
54
15
8
1.0
394
Interface: AB-BC: Path-1
Total From MW Flow: 850.19 MW
Interface: BC-US: Path-3
Total From MW Flow: -848.88 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -0.44 MW
54
23
2
CO
LE
MA
N9138.
1.0
244
54
23
2
CO
LE
MA
N9138.
1.0
244
50
77
6
NT
L 1
38 1
38.
1.0
268
50
77
6
NT
L 1
38 1
38.
1.0
268
50
83
0
BC
K 2
74P
138.
0.9
856
50
83
0
BC
K 2
74P
138.
0.9
856
54
32
9
PO
CA
TE
R7138.
1.0
432
54
32
9
PO
CA
TE
R7138.
1.0
432
1L2741L274
13hw2ae_case1a_P1_08505
07
69
KC
L 1
3G
113.8
1.0
148
0.001
-24.59
50
76
9
KC
L 1
3G
113.8
1.0
148
0.001
-24.59
50
77
0
KC
L 1
3G
213.8
1.0
355
2
50
77
0
KC
L 1
3G
213.8
1.0
355
2
50
77
1
KC
L 1
3G
313.8
1.0
355
3
50
77
1
KC
L 1
3G
313.8
1.0
355
3
50
77
2
KC
L 1
3G
413.8
1.0
355
4
50
77
2
KC
L 1
3G
413.8
1.0
355
4
50766
SEV 13G113.8 1.0351
0.0
01
-4.1
7
50766
SEV 13G113.8 1.0351
0.0
01
-4.1
7
50767
SEV 13G213.8 1.0374
2
50767
SEV 13G213.8 1.0374
2
50768
SEV 13G313.8 1.0376
3
50768
SEV 13G313.8 1.0376
3
51036
SEV 13G413.8 1.0376
4
51036
SEV 13G413.8 1.0376
4
50786
INV 230 230. 1.0342
50786
INV 230 230. 1.0342
84.36
-41.17
-83.0
3
26.1
6
2L
25
8
84.36
-41.17
-83.0
3
26.1
6
2L
25
8
-37.78
13.04
38.32
-13.88
1L275 -37.78
13.04
38.32
-13.88
1L275
0.0
0
0.0
0
-793.64
125.80
811.87
-51.68
5L94 -793.64
125.80
811.87
-51.68
5L94
0.0
0
-132.5
6
Report No. T&S Planning – 2013-058 Page 25
Not to be reproduced without the permission of BC Hydro
50
79
1
0.9
848
CB
K 5
00 5
00.
50822
1.0382NLY 2PS2230.
50784
1.0311NLY 230 230.
251.5
5-2
50.8
1
22.3
73.6
7
50
79
1
50822
50784
251.5
5-2
50.8
1
1.0311
22.3
73.6
7
NLY 230 230.
1.0382NLY 2PS2230.
0.9
848
CB
K 5
00 5
00.
50792
1.0342SEL 500 500.
0.0
0
0.0
0
1166.8
3
-1143.74
5L
92
169.4
5
46.17
51352
0.9232CBK 12T212.6
0.0
0
0.0
0
51353
0.9232CBK 12T312.6
50792
51352
51353
1166.8
3
-1143.74
1.0342
0.9232CBK 12T312.6
0.9232CBK 12T212.6
5L
92
169.4
5
46.17
SEL 500 500.
50
78
2
0.9
702
CB
K 2
30 2
30.
-0.00
-0.00
30.71
-41.43
-30.03
41.44
50
78
2
0.9
702
CB
K 2
30 2
30.
-0.00
-0.00
30.71
-41.43
-30.03
41.44
0.00
0.00
30.73
-41.46
-30.05
41.47
80
64
1
0.9
810
SE
L 1
2T
112.6
80
30
6
0.9
810
SE
L 1
2T
412.6
80
30
5
0.9
810
SE
L 1
2T
312.6
80
64
1
80
30
6
80
30
5
0.9
810
SE
L 1
2T
312.6
0.9
810
SE
L 1
2T
412.6
0.9
810
SE
L 1
2T
112.6
0.00
0.00
30.73
-41.46
-30.05
41.47
80
30
4
0.9
811
SE
L 1
2T
212.6
50783
1.0326SEL 230 230.
0.00
0.00
-20.56
204.53
26.75
-204.44
80
30
4
50783
1.0326SEL 230 230.
0.00
0.00
-20.56
204.53
26.75
-204.44
0.9
811
SE
L 1
2T
212.6
0.00
0.00
-15.05
149.72
19.58
-149.66
0.00
0.00
-14.91
148.25
19.39
-148.18
0.00
0.00
-15.05
0.00
0.00
-14.91
148.25
19.39
-148.18
149.72
19.58
-149.66
-0.00
-0.00
-20.59
204.74
26.78
-204.65
156.2
9
-155.7
7
2L293
-32.4
4
32.9
4
80640
0.9908AAL 2T3 230.
-238.7
7244.3
52
L2
94
-15.4
339.9
7
-0.00
80640
156.2
9
-238.7
7244.3
5
-155.7
7
0.9908
2L
29
4-1
5.4
339.9
7
AAL 2T3 230.
2L293
-32.4
4
32.9
4
-0.00
-20.59
204.74
26.78
-204.65
50
70
2
1.0
642
AC
K 5
00 5
00.
51
13
4
1.0
523
VA
S 5
00 5
00.
50
78
8
1.0
360
KC
L 2
30 2
30.
0.10
0.21
103.09
-102.4
8
2L295
-8.89
4.2
6
50
70
2
51
13
4
50
78
8
103.09
-102.4
8
1.0
360
2L295
-8.89
4.2
6
KC
L 2
30 2
30.
1.0
523
VA
S 5
00 5
00.
1.0
642
AC
K 5
00 5
00.
103.00
-102.3
9
2L299
-8.87
4.2
4
CBK
103.00
-102.3
9
0.10
0.21
SEL
2L299
-8.87
4.2
4
ACK
VAS
KCL
AAL
NLY
50789
0.9908AAL 2T1 230. 205.3
6
-199.67
2L
29
4
3.4
1
18.72
238.7
7-2
38.7
7
15.4
3-1
5.4
3
50785
1.0328SEV 2T1 230.
50789
205.3
6
50785
238.7
7-2
38.7
7
-199.67
0.9908
2L
29
4
1.0328SEV 2T1 230.
15.4
3-1
5.4
33.4
1
18.72
AAL 2T1 230.
194.2
1-1
94.1
22
L2
21
-11.2
311.1
3
51350
1.0326SEV 2T3 230. -0.2
00.2
02
L2
22
-0.1
1-0
.80
-440.7
8
444.56
5L
91
-199.4
3
85.78
51350
194.2
1
-0.2
0
-440.7
8
444.56
0.2
0
-194.1
2
1.0326
2L
22
2
5L
91
-199.4
3
85.78
-0.1
1-0
.80
SEV 2T3 230.
2L
22
1
-11.2
311.1
3
19.23
-19.1
1
5L
96
-24.14
-62.5
2
SEV40146
1.0400BOUNDRYW230.
-251.5
5251.8
12
L1
12
-22.3
623.7
2
50787
0.9516NTL 230 230.
19.23
40146
-19.1
1
50787
-251.5
5251.8
1
5L
96
1.0400
0.9516NTL 230 230.
2L
11
2-2
2.3
623.7
2
BOUNDRYW230.
-24.14
-62.5
2
5.86
-7.5
8
2L
11
3-1
15.5
6
117.20
5.86
-7.5
8
2L
11
3
LA
NG
DO
N2500.
54
15
8
1.0
130
-115.5
6
117.20
LA
NG
DO
N2500.
54
15
8
1.0
130
Interface: AB-BC: Path-1
Total From MW Flow: 1098.80 MW
Interface: BC-US: Path-3
Total From MW Flow: -1095.51 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -58.93 MW
54
23
2
CO
LE
MA
N9138.
1.0
277
54
23
2
CO
LE
MA
N9138.
1.0
277
50
77
6
NT
L 1
38 1
38.
1.0
317
50
77
6
NT
L 1
38 1
38.
1.0
317
50
83
0
BC
K 2
74P
138.
0.9
908
50
83
0
BC
K 2
74P
138.
0.9
908
54
32
9
PO
CA
TE
R7138.
1.0
417
54
32
9
PO
CA
TE
R7138.
1.0
417
1L2741L274
13hw2ae_case2a_P1_11005
07
69
KC
L 1
3G
113.8
1.0
407
69.001
6.11
50
76
9
KC
L 1
3G
113.8
1.0
407
69.001
6.11
50
77
0
KC
L 1
3G
213.8
1.0
355
2
50
77
0
KC
L 1
3G
213.8
1.0
355
2
50
77
1
KC
L 1
3G
313.8
1.0
355
3
50
77
1
KC
L 1
3G
313.8
1.0
355
3
50
77
2
KC
L 1
3G
413.8
1.0
355
4
50
77
2
KC
L 1
3G
413.8
1.0
355
4
50766
SEV 13G113.8 1.0351
195.0
01
9.7
6
50766
SEV 13G113.8 1.0351
195.0
01
9.7
6
50767
SEV 13G213.8 1.0323
2
50767
SEV 13G213.8 1.0323
2
50768
SEV 13G313.8 1.0321
3
50768
SEV 13G313.8 1.0321
3
51036
SEV 13G413.8 1.0321
4
51036
SEV 13G413.8 1.0321
4
50786
INV 230 230. 0.9949
50786
INV 230 230. 0.9949
84.35
-38.62
-82.9
3
26.0
5
2L
25
8
84.35
-38.62
-82.9
3
26.0
5
2L
25
8
-37.46
10.90
37.97
-11.83
1L275 -37.46
10.90
37.97
-11.83
1L275
0.0
0
0.0
0
-1026.94
289.08
1060.84
13.86
5L94 -1026.94
289.08
1060.84
13.86
5L94
0.0
0
0.0
0
Report No. T&S Planning – 2013-058 Page 26
Not to be reproduced without the permission of BC Hydro
50
79
1
0.9
498
CB
K 5
00 5
00.
50822
1.0371NLY 2PS2230.
50784
1.0192NLY 230 230.
250.8
3-2
50.1
7
53.1
3-3
0.1
2
50
79
1
50822
50784
250.8
3-2
50.1
7
1.0192
53.1
3-3
0.1
2
NLY 230 230.
1.0371NLY 2PS2230.
0.9
498
CB
K 5
00 5
00.
50792
1.0153SEL 500 500.
0.0
0
0.0
0
1247.6
9
-1219.49
5L
92
264.9
1
25.07
51352
0.8874CBK 12T212.6
0.0
0
0.0
0
51353
0.8874CBK 12T312.6
50792
51352
51353
1247.6
9
-1219.49
1.0153
0.8874CBK 12T312.6
0.8874CBK 12T212.6
5L
92
264.9
1
25.07
SEL 500 500.
50
78
2
0.9
330
CB
K 2
30 2
30.
-0.00
0.00
17.80
-29.42
-17.47
29.42
50
78
2
0.9
330
CB
K 2
30 2
30.
-0.00
0.00
17.80
-29.42
-17.47
29.42
-0.00
0.00
17.81
-29.44
-17.48
29.44
80
64
1
0.9
672
SE
L 1
2T
112.6
80
30
6
0.9
672
SE
L 1
2T
412.6
80
30
5
0.9
671
SE
L 1
2T
312.6
80
64
1
80
30
6
80
30
5
0.9
671
SE
L 1
2T
312.6
0.9
672
SE
L 1
2T
412.6
0.9
672
SE
L 1
2T
112.6
-0.00
0.00
17.81
-29.44
-17.48
29.44
80
30
4
0.9
671
SE
L 1
2T
212.6
50783
1.0171SEL 230 230.
-0.00
-0.00
11.85
474.71
22.19
-474.22
80
30
4
50783
1.0171SEL 230 230.
-0.00
-0.00
11.85
474.71
22.19
-474.22
0.9
671
SE
L 1
2T
212.6
-0.00
0.00
8.69
347.51
16.23
-347.16
-0.00
-0.00
8.58
344.09
16.09
-343.73
-0.00
0.00
8.69
-0.00
-0.00
8.58
344.09
16.09
-343.73
347.51
16.23
-347.16
0.00
-0.00
11.85
475.20
22.22
-474.71
131.7
1
-131.3
5
2L293
-4.9
6
4.4
7
80640
0.9622AAL 2T3 230.
-271.4
5279.1
42
L2
94
-28.0
866.9
2
0.00
80640
131.7
1
-271.4
5279.1
4
-131.3
5
0.9622
2L
29
4-2
8.0
866.9
2
AAL 2T3 230.
2L293
-4.9
6
4.4
7
-0.00
11.85
475.20
22.22
-474.71
50
70
2
1.0
481
AC
K 5
00 5
00.
51
13
4
1.0
356
VA
S 5
00 5
00.
50
78
8
1.0
360
KC
L 2
30 2
30.
0.10
0.21
240.71
-237.3
6
2L295
18.23
-3.8
9
50
70
2
51
13
4
50
78
8
240.71
-237.3
6
1.0
360
2L295
18.23
-3.8
9
KC
L 2
30 2
30.
1.0
356
VA
S 5
00 5
00.
1.0
481
AC
K 5
00 5
00.
240.48
-237.1
4
2L299
18.24
-3.9
3
CBK
240.48
-237.1
4
0.10
0.21
SEL
2L299
18.24
-3.9
3
ACK
VAS
KCL
AAL
NLY
50789
0.9622AAL 2T1 230. 238.0
0
-229.85
2L
29
4
15.8
4
23.76
271.4
5-2
71.4
5
28.0
8-2
8.0
8
50785
1.0183SEV 2T1 230.
50789
238.0
0
50785
271.4
5-2
71.4
5
-229.85
0.9622
2L
29
4
1.0183SEV 2T1 230.
28.0
8-2
8.0
815.8
4
23.76
AAL 2T1 230.
388.7
5-3
88.3
72
L2
21
11.5
9-9
.16
51350
1.0189SEV 2T3 230. 383.8
1-3
83.4
32
L2
22
36.2
3-3
3.8
5
-9.1
9
9.46
5L
91
-257.4
3
100.13
51350
388.7
5
383.8
1
-9.1
9
9.46
-383.4
3
-388.3
7
1.0189
2L
22
2
5L
91
-257.4
3
100.13
36.2
3-3
3.8
5
SEV 2T3 230.
2L
22
1
11.5
9-9
.16
-398.78
401.3
4
5L
96
34.72
-84.2
1
SEV40146
1.0400BOUNDRYW230.
-250.8
3251.1
02
L1
12
-53.1
454.5
7
50787
0.9129NTL 230 230.
-398.78
40146
401.3
4
50787
-250.8
3251.1
0
5L
96
1.0400
0.9129NTL 230 230.
2L
11
2-5
3.1
454.5
7
BOUNDRYW230.
34.72
-84.2
1
7.50
-6.3
8
2L
11
3-1
20.1
5
122.07
7.50
-6.3
8
2L
11
3
LA
NG
DO
N2500.
54
15
8
1.0
072
-120.1
5
122.07
LA
NG
DO
N2500.
54
15
8
1.0
072
Interface: AB-BC: Path-1
Total From MW Flow: 1204.66 MW
Interface: BC-US: Path-3
Total From MW Flow: -833.44 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -19.60 MW
54
23
2
CO
LE
MA
N9138.
1.0
222
54
23
2
CO
LE
MA
N9138.
1.0
222
50
77
6
NT
L 1
38 1
38.
1.0
244
50
77
6
NT
L 1
38 1
38.
1.0
244
50
83
0
BC
K 2
74P
138.
0.9
830
50
83
0
BC
K 2
74P
138.
0.9
830
54
32
9
PO
CA
TE
R7138.
1.0
428
54
32
9
PO
CA
TE
R7138.
1.0
428
1L2741L274
13hw2ae_case3_P1_12005
07
69
KC
L 1
3G
113.8
1.0
574
123.491
29.38
50
76
9
KC
L 1
3G
113.8
1.0
574
123.491
29.38
50
77
0
KC
L 1
3G
213.8
1.0
574
123.492
29.38
50
77
0
KC
L 1
3G
213.8
1.0
574
123.492
29.38
50
77
1
KC
L 1
3G
313.8
1.0
579
123.493
29.38
50
77
1
KC
L 1
3G
313.8
1.0
579
123.493
29.38
50
77
2
KC
L 1
3G
413.8
1.0
579
123.494
29.38
50
77
2
KC
L 1
3G
413.8
1.0
579
123.494
29.38
50766
SEV 13G113.8 1.0351
195.0
01
35.3
3
50766
SEV 13G113.8 1.0351
195.0
01
35.3
3
50767
SEV 13G213.8 1.0314
195.0
02
29.0
8
50767
SEV 13G213.8 1.0314
195.0
02
29.0
8
50768
SEV 13G313.8 1.0353
195.0
03
34.6
5
50768
SEV 13G313.8 1.0353
195.0
03
34.6
5
51036
SEV 13G413.8 1.0352
190.0
04
40.1
451036
SEV 13G413.8 1.0352
190.0
04
40.1
4
50786
INV 230 230. 0.9420
50786
INV 230 230. 0.9420
83.69
-24.32
-82.2
8
13.6
6
2L
25
8
83.69
-24.32
-82.2
8
13.6
6
2L
25
8
-43.30
16.05
44.03
-16.47
1L275 -43.30
16.05
44.03
-16.47
1L275
0.0
0
0.0
0
-1117.12
433.21
1160.64
9.82
5L94 -1117.12
433.21
1160.64
9.82
5L94
0.0
0
0.0
0
Report No. T&S Planning – 2013-058 Page 27
Not to be reproduced without the permission of BC Hydro
50
79
1
0.9
612
CB
K 5
00 5
00.
50822
1.0377NLY 2PS2230.
50784
1.0256NLY 230 230.
251.8
5-2
51.0
8
34.3
1-7
.63
50
79
1
50822
50784
251.8
5-2
51.0
8
1.0256
34.3
1-7
.63
NLY 230 230.
1.0377NLY 2PS2230.
0.9
612
CB
K 5
00 5
00.
50792
1.0267SEL 500 500.
0.0
0
0.0
0
1265.7
1
-1237.37
5L
92
264.8
4
24.92
51352
0.9002CBK 12T212.6
0.0
0
0.0
0
51353
0.9002CBK 12T312.6
50792
51352
51353
1265.7
1
-1237.37
1.0267
0.9002CBK 12T312.6
0.9002CBK 12T212.6
5L
92
264.8
4
24.92
SEL 500 500.
50
78
2
0.9
462
CB
K 2
30 2
30.
0.00
-0.00
25.84
-35.01
-25.33
35.01
50
78
2
0.9
462
CB
K 2
30 2
30.
0.00
-0.00
25.84
-35.01
-25.33
35.01
0.00
-0.00
25.86
-35.04
-25.35
35.04
80
64
1
0.9
761
SE
L 1
2T
112.6
80
30
6
0.9
761
SE
L 1
2T
412.6
80
30
5
0.9
761
SE
L 1
2T
312.6
80
64
1
80
30
6
80
30
5
0.9
761
SE
L 1
2T
312.6
0.9
761
SE
L 1
2T
412.6
0.9
761
SE
L 1
2T
112.6
0.00
-0.00
25.86
-35.04
-25.35
35.04
80
30
4
0.9
761
SE
L 1
2T
212.6
50783
1.0271SEL 230 230.
0.00
0.00
-6.89
231.12
14.81
-231.01
80
30
4
50783
1.0271SEL 230 230.
0.00
0.00
-6.89
231.12
14.81
-231.01
0.9
761
SE
L 1
2T
212.6
-0.00
-0.00
-5.04
169.19
10.83
-169.11
0.00
0.00
-5.00
167.53
10.74
-167.44
-0.00
-0.00
-5.04
0.00
0.00
-5.00
167.53
10.74
-167.44
169.19
10.83
-169.11
0.00
-0.00
-6.90
231.36
14.83
-231.25
143.4
0
-142.9
6
2L293
-30.7
7
30.7
8
80640
0.9747AAL 2T3 230.
-254.1
2260.6
92
L2
94
-25.6
856.9
1
0.00
80640
143.4
0
-254.1
2260.6
9
-142.9
6
0.9747
2L
29
4-2
5.6
856.9
1
AAL 2T3 230.
2L293
-30.7
7
30.7
8
-0.00
-6.90
231.36
14.83
-231.25
50
70
2
1.0
652
AC
K 5
00 5
00.
51
13
4
1.0
505
VA
S 5
00 5
00.
50
78
8
1.0
360
KC
L 2
30 2
30.
0.10
0.21
126.50
-125.5
8
2L295
2.25
-4.7
0
50
70
2
51
13
4
50
78
8
126.50
-125.5
8
1.0
360
2L295
2.25
-4.7
0
KC
L 2
30 2
30.
1.0
505
VA
S 5
00 5
00.
1.0
652
AC
K 5
00 5
00.
126.38
-125.4
6
2L299
2.26
-4.7
2
CBK
126.38
-125.4
6
0.10
0.21
SEL
2L299
2.26
-4.7
2
ACK
VAS
KCL
AAL
NLY
50789
0.9747AAL 2T1 230. 220.7
0
-213.87
2L
29
4
13.5
4
16.83
254.1
2-2
54.1
2
25.6
8-2
5.6
8
50785
1.0273SEV 2T1 230.
50789
220.7
0
50785
254.1
2-2
54.1
2
-213.87
0.9747
2L
29
4
1.0273SEV 2T1 230.
25.6
8-2
5.6
813.5
4
16.83
AAL 2T1 230.
116.6
4-1
16.6
12
L2
21
-1.7
71.1
7
51350
1.0275SEV 2T3 230. 116.5
9-1
16.5
62
L2
22
7.2
0-7
.80
-434.2
9
438.09
5L
91
-227.7
5
116.55
51350
116.6
4
116.5
9
-434.2
9
438.09
-116.5
6
-116.6
1
1.0275
2L
22
2
5L
91
-227.7
5
116.55
7.2
0-7
.80
SEV 2T3 230.
2L
22
1
-1.7
71.1
7
32.80
-32.6
0
5L
96
2.88
-88.3
0
SEV40146
1.0400BOUNDRYW230.
-251.8
5252.1
12
L1
12
-34.3
235.7
1
50787
0.9259NTL 230 230.
32.80
40146
-32.6
0
50787
-251.8
5252.1
1
5L
96
1.0400
0.9259NTL 230 230.
2L
11
2-3
4.3
235.7
1
BOUNDRYW230.
2.88
-88.3
0
7.92
-8.2
8
2L
11
3-1
16.1
5
117.90
7.92
-8.2
8
2L
11
3
LA
NG
DO
N2500.
54
15
8
1.0
095
-116.1
5
117.90
LA
NG
DO
N2500.
54
15
8
1.0
095
Interface: AB-BC: Path-1
Total From MW Flow: 1206.90 MW
Interface: BC-US: Path-3
Total From MW Flow: -1203.97 MW
Interface: AB-MONTANA: Path-MATL
Total From MW Flow: -101.08 MW
54
23
2
CO
LE
MA
N9138.
1.0
298
54
23
2
CO
LE
MA
N9138.
1.0
298
50
77
6
NT
L 1
38 1
38.
1.0
334
50
77
6
NT
L 1
38 1
38.
1.0
334
50
83
0
BC
K 2
74P
138.
0.9
926
50
83
0
BC
K 2
74P
138.
0.9
926
54
32
9
PO
CA
TE
R7138.
1.0
380
54
32
9
PO
CA
TE
R7138.
1.0
380
1L2741L27413hw2ae_case3b_P1_1200
50
76
9
KC
L 1
3G
113.8
1.0
355
1
50
76
9
KC
L 1
3G
113.8
1.0
355
1
50
77
0
KC
L 1
3G
213.8
1.0
355
2
50
77
0
KC
L 1
3G
213.8
1.0
355
2
50
77
1
KC
L 1
3G
313.8
1.0
519
70.003
19.40
50
77
1
KC
L 1
3G
313.8
1.0
519
70.003
19.40
50
77
2
KC
L 1
3G
413.8
1.0
518
70.004
19.40
50
77
2
KC
L 1
3G
413.8
1.0
518
70.004
19.40
50766
SEV 13G113.8 1.0268
1
50766
SEV 13G113.8 1.0268
1
50767
SEV 13G213.8 1.0314
117.0
02
9.3
8
50767
SEV 13G213.8 1.0314
117.0
02
9.3
8
50768
SEV 13G313.8 1.0353
117.0
03
14.9
4
50768
SEV 13G313.8 1.0353
117.0
03
14.9
4
51036
SEV 13G413.8 1.0270
4
51036
SEV 13G413.8 1.0270
4
50786
INV 230 230. 0.9666
50786
INV 230 230. 0.9666
83.82
-33.97
-82.3
8
22.7
1
2L
25
8
83.82
-33.97
-82.3
8
22.7
1
2L
25
8
-39.03
12.05
39.58
-12.88
1L275 -39.03
12.05
39.58
-12.88
1L275
0.0
0
0.0
0
-1124.24
409.06
1167.32
25.71
5L94 -1124.24
409.06
1167.32
25.71
5L94
0.0
0
0.0
0
Report No. T&S Planning – 2013-058 Page 28
Not to be reproduced without the permission of BC Hydro
APPENDIX B – CONTINGENCIES
The following table lists the contintencies applied in post contingency power flows and transient
stability analses. The contingencies used in the heavy summer and heavy winter cases are identical
while the RAS control actions could differ depending on the actual flows, etc. For transient
stability simulation, the switching sequence consisted of 3-phase fault applied at either side of the
device, followed by subsequent trip out by protection. Appropriate RAS actions were applied
where applicable, according to BCH operating order instructions. Multiple devices in the same
protection zone are regarded as a single contingency and are tripped with timings according to
protection settings. For post disturbance steady-state performance simulation, post contingency
power flows were performed with all applicable protection and RAS actions and automatically
controlled devices turned on.
Contingency Name Contingency Description Comment
SEL T1 SEL T1 contingency and trip out
SEL T2 & T3 Contingency on SEL T2 or T3, Trip out both T2 & T3
SEL T2 & T3 in the same protection zone
CBK T2 & T6 Contingency on CBK T2 or T6, Trip out both T2 & T6
CBK T2 & T6 in the same protection zone
5L71 MCA-NIC 5L71 contingency and trip out, Generation shedding applied at MCA
5L75 REV-ACK 5L71 contingency and trip out
5L76 ACK-NIC 5L76 contingency and trip out
5L81 NIC-ING 5L81 contingency and trip out Series-compensated line
5L82 NIC-MDN 5L82 contingency and trip out Series-compensated line
5L87 NIC-KLY 5L87 contingency and trip out Series-compensated line
5L91 ACK-SEL 5L91 contingency and trip out
5L92 CBK-SEL 5L92 contingency and trip out During high transfer, loss of 5L92 would result in tripping 5L94 and separation of 138kV ties with AB. Appropriate amount of generation shedding was applied in BCH.
5L94 trip out
Open 1L275 at Natal
Open 1L274 at Britt Creek if normally closed
Trip open MATL
Generation shedding applied in BCH
5L94 CBK-LGN 5L94 contingency and trip out During high transfer, loss of 5L94 would result in tripping open 138kV ties with AB. Appropriate amount of generation shedding was applied in BCH.
Open 1L275 at Natal
Open 1L274 at Britt Creek if normally closed
Report No. T&S Planning – 2013-058 Page 29
Not to be reproduced without the permission of BC Hydro
Trip open MATL Generation shedding applied in BCH
5L96 VAS-SEL 5L96 contingency and trip out
48L (BEN-KET 161) tripped by RAS
5L98 NIC-VAS 5L98 contingency and trip out
2L112 NLY-BDY 2L112 contingency and trip out
2L221 SEV-SEL 2L221 contingency and trip out
2L277 WAN-NLY 2L277 contingency and trip out , generation shedding at WAN
For the winter case, generation shedding applied to maintain transient stability
2L288 KCL-BTS 2L288 contingency and trip out
2L289 SEL-BTS 2L289 contingency and trip out
2L293 SEL-NLY 2L293 contingency and trip out
2L294 CBK-NLY 2L294 contingency and trip out
2L295 SEL-KCL 2L295 contingency and trip out
1L274 NTL-POCATER 1L274 contingency and trip out
1L275 NTL-COLEMAN 1L275 contingency and trip out
Report No. T&S Planning – 2013-058 Page 30
Not to be reproduced without the permission of BC Hydro
APPENDIX C – POWER FLOW CONTINGENCY RESULTS
The tables in this appendix show more detailed contingecy analysis results for BC to AB transfers
of 1100 MW (heavy winter) and 1200 MW(heavy winter and heavy summer).
Report No. T&S Planning – 2013-058 Page 31
Not to be reproduced without the permission of BC Hydro
HS Case 3 – 1200 MW BC to AB
Cont. Name NIC 500 ACK 500 SEL 500 SEL 230 VAS 500 CBK 500 CBK 230 NTL 230 NTL 138 NLY 230
LNGDN 500
[50703] [50702] [50792] [50783] [51134] [50791] [50782] [50787] [50776] [50784] [54158]
Pre Contingency 1.054 1.060 1.042 1.037 1.062 0.987 0.974 0.942 1.032 1.028 1.018
SEL T1 1.054 1.060 1.043 1.036 1.063 0.988 0.974 0.942 1.033 1.027 1.018
SEL T2&T3 1.054 1.060 1.044 1.035 1.063 0.988 0.974 0.942 1.032 1.026 1.018
CBK T2&T6 1.053 1.060 1.041 1.036 1.062 0.982 0.973 0.942 1.032 1.028 1.017
5L71 MCA-NIC 1.029 1.045 1.034 1.032 1.044 0.980 0.968 0.937 1.029 1.024 1.016
5L75 REV-ACK 1.047 1.048 1.038 1.034 1.056 0.984 0.971 0.940 1.030 1.026 1.017
5L76 ACK-NIC 1.043 1.051 1.036 1.033 1.052 0.982 0.970 0.938 1.029 1.024 1.016
5L81 NIC-ING 1.039 1.052 1.036 1.033 1.051 0.982 0.969 0.938 1.029 1.021 1.016
5L82 NIC-MDN 1.039 1.052 1.037 1.033 1.051 0.982 0.970 0.939 1.030 1.021 1.017
5L87 NIC-KLY 1.045 1.056 1.039 1.035 1.056 0.985 0.972 0.940 1.031 1.026 1.017
5L91 ACK-SEL 1.049 1.058 1.025 1.027 1.051 0.973 0.962 0.932 1.024 1.022 1.014
5L96 VAS-SEL 1.050 1.056 1.026 1.027 1.055 0.974 0.962 0.932 1.025 1.019 1.015
5L98 NIC-VAS 1.047 1.057 1.040 1.035 1.056 0.985 0.972 0.941 1.031 1.027 1.017
2L112 NLY-BDY 1.049 1.057 1.040 1.035 1.058 0.986 0.972 0.940 1.031 1.029 1.017
2L221 SEV-SEL 1.050 1.055 1.038 1.034 1.058 0.984 0.972 0.940 1.031 1.027 1.017
2L277 WAN-NLY 1.053 1.060 1.041 1.036 1.062 0.986 0.973 0.941 1.032 1.026 1.017
2L288 KCL-BTS 1.053 1.060 1.041 1.036 1.062 0.986 0.974 0.942 1.032 1.028 1.018
2L289 SEL-BTS 1.054 1.060 1.042 1.037 1.062 0.987 0.974 0.942 1.033 1.029 1.018
2L293 SEL-NLY 1.050 1.058 1.039 1.036 1.058 0.983 0.974 0.943 1.033 1.028 1.017
2L294 CBK-NLY 1.053 1.059 1.035 1.033 1.059 0.968 0.956 0.922 1.035 1.031 1.013
2L295 SEL-KCL 1.053 1.060 1.041 1.036 1.062 0.986 0.974 0.942 1.032 1.028 1.018
1L274 NTL-POCATER 1.055 1.061 1.045 1.039 1.064 0.995 0.984 0.973 1.033 1.030 1.019
1L275 NTL-COLEMAN 1.053 1.060 1.040 1.036 1.061 0.980 0.969 0.941 1.033 1.027 1.013
5L92 CBK-SEL 1.058 1.061 1.048 1.040 1.062 1.047 1.024 1.000 1.031 1.024 0.000
5L94 CBK-LGN 1.060 1.063 1.056 1.045 1.067 1.054 1.032 1.007 1.038 1.030 0.000
Report No. T&S Planning – 2013-058 Page 32
Not to be reproduced without the permission of BC Hydro
HS Case 3a – 1200 MW BC to AB
Cont. Name NIC 500 ACK 500 SEL 500 SEL 230 VAS 500 CBK 500 CBK 230 NTL 230 NTL 138 NLY 230 LNGDN
500
[50703] [50702] [50792] [50783] [51134] [50791] [50782] [50787] [50776] [50784] [54158]
Pre Contingency 1.059 1.063 1.044 1.041 1.065 0.988 0.974 0.946 1.036 1.034 1.018
SEL T1 1.060 1.063 1.045 1.040 1.066 0.989 0.975 0.947 1.036 1.034 1.018
SEL T2&T3 1.060 1.064 1.046 1.040 1.066 0.989 0.975 0.947 1.036 1.033 1.018
CBK T2&T6 1.059 1.063 1.043 1.040 1.065 0.983 0.973 0.945 1.035 1.033 1.017
5L71 MCA-NIC 1.036 1.049 1.035 1.035 1.047 0.981 0.968 0.941 1.031 1.030 1.016
5L75 REV-ACK 1.054 1.053 1.040 1.038 1.059 0.985 0.972 0.944 1.034 1.032 1.017
5L76 ACK-NIC 1.051 1.055 1.039 1.037 1.058 0.984 0.971 0.943 1.033 1.031 1.017
5L81 NIC-ING 1.046 1.056 1.039 1.037 1.055 0.984 0.971 0.944 1.034 1.031 1.017
5L82 NIC-MDN 1.048 1.057 1.039 1.037 1.055 0.984 0.971 0.944 1.034 1.031 1.017
5L87 NIC-KLY 1.053 1.060 1.042 1.039 1.061 0.986 0.973 0.945 1.035 1.033 1.018
5L91 ACK-SEL 1.049 1.058 1.019 1.024 1.039 0.968 0.956 0.931 1.024 1.024 1.013
5L96 VAS-SEL 1.057 1.059 1.023 1.027 1.062 0.972 0.960 0.934 1.026 1.025 1.014
5L98 NIC-VAS 1.052 1.057 1.037 1.036 1.051 0.982 0.969 0.942 1.032 1.031 1.017
2L112 NLY-BDY 1.059 1.063 1.044 1.040 1.065 0.988 0.974 0.946 1.035 1.033 1.018
2L221 SEV-SEL 1.057 1.059 1.039 1.037 1.061 0.984 0.971 0.944 1.034 1.032 1.017
2L277 WAN-NLY 1.059 1.063 1.044 1.040 1.065 0.988 0.974 0.946 1.036 1.033 1.018
2L288 KCL-BTS 1.059 1.063 1.044 1.040 1.065 0.988 0.974 0.946 1.035 1.034 1.018
2L289 SEL-BTS 1.060 1.063 1.045 1.042 1.066 0.989 0.975 0.947 1.036 1.035 1.018
2L293 SEL-NLY 1.058 1.063 1.045 1.042 1.065 0.987 0.976 0.948 1.036 1.030 1.018
2L294 CBK-NLY 1.058 1.062 1.036 1.036 1.061 0.968 0.956 0.932 1.024 1.036 1.013
2L295 SEL-KCL 1.059 1.063 1.044 1.041 1.065 0.988 0.974 0.946 1.036 1.034 1.018
1L274 NTL-POCATER 1.060 1.064 1.048 1.043 1.068 0.997 0.986 0.982 1.030 1.036 1.020
1L275 NTL-COLEMAN 1.059 1.063 1.042 1.040 1.064 0.982 0.970 0.949 1.032 1.033 1.014
5L92 CBK-SEL 1.072 1.073 1.072 1.059 1.085 1.044 1.021 1.004 1.026 1.045 0.000
5L94 CBK-LGN 1.070 1.072 1.077 1.062 1.086 1.062 1.032 1.014 1.024 1.049 0.000
Report No. T&S Planning – 2013-058 Page 33
Not to be reproduced without the permission of BC Hydro
HW Case 2a – 1100 MW BC to AB
Cont. Name NIC 500 ACK 500 SEL 500 SEL 230 VAS 500 CBK 500 CBK 230 NTL 230 NTL 138 NLY 230
LNGDN 500
[50703] [50702] [50792] [50783] [51134] [50791] [50782] [50787] [50776] [50784] [54158]
Pre Contingency 1.052 1.064 1.034 1.033 1.053 0.985 0.971 0.952 1.032 1.031 1.013
SEL T1 1.052 1.065 1.035 1.032 1.053 0.985 0.970 0.952 1.032 1.031 1.013
SEL T2&T3 1.052 1.065 1.035 1.032 1.053 0.986 0.971 0.952 1.032 1.030 1.014
CBK T2&T6 1.052 1.064 1.032 1.031 1.052 0.978 0.965 0.948 1.029 1.030 1.009
5L71 MCA-NIC 1.032 1.051 1.026 1.027 1.037 0.977 0.963 0.945 1.027 1.027 1.009
5L75 REV-ACK 1.052 1.060 1.033 1.032 1.051 0.984 0.969 0.951 1.031 1.031 1.012
5L76 ACK-NIC 1.045 1.060 1.030 1.030 1.047 0.980 0.965 0.947 1.028 1.029 1.010
5L81 NIC-ING 1.044 1.059 1.030 1.030 1.046 0.977 0.963 0.945 1.027 1.029 1.007
5L82 NIC-MDN 1.043 1.059 1.029 1.030 1.045 0.977 0.963 0.945 1.026 1.029 1.007
5L87 NIC-KLY 1.047 1.062 1.032 1.031 1.049 0.982 0.967 0.949 1.030 1.030 1.011
5L91 ACK-SEL 1.047 1.064 1.005 1.011 1.033 0.961 0.947 0.925 1.038 1.016 1.004
5L96 VAS-SEL 1.050 1.063 1.028 1.028 1.047 0.979 0.964 0.947 1.028 1.028 1.010
5L98 NIC-VAS 1.047 1.060 1.026 1.027 1.032 0.979 0.965 0.947 1.028 1.027 1.011
2L112 NLY-BDY 1.055 1.066 1.036 1.035 1.055 0.992 0.978 0.958 1.037 1.030 1.020
2L221 SEV-SEL 1.052 1.063 1.033 1.032 1.052 0.985 0.970 0.951 1.031 1.031 1.013
2L277 WAN-NLY 1.054 1.065 1.032 1.029 1.052 0.982 0.967 0.949 1.030 1.026 1.011
2L288 KCL-BTS 1.052 1.064 1.034 1.032 1.052 0.984 0.970 0.951 1.032 1.031 1.013
2L289 SEL-BTS 1.052 1.064 1.034 1.032 1.052 0.984 0.970 0.951 1.031 1.030 1.013
2L293 SEL-NLY 1.055 1.066 1.037 1.035 1.055 0.986 0.968 0.950 1.031 1.026 1.014
2L294 CBK-NLY 1.051 1.063 1.026 1.027 1.048 0.964 0.951 0.931 1.034 1.034 1.004
2L295 SEL-KCL 1.052 1.064 1.033 1.031 1.052 0.984 0.969 0.951 1.031 1.030 1.013
1L274 NTL-POCATER 1.054 1.066 1.039 1.036 1.055 0.997 0.985 0.993 1.030 1.034 1.019
1L275 NTL-COLEMAN 1.052 1.064 1.033 1.032 1.052 0.980 0.966 0.952 1.034 1.031 1.007
5L92 CBK-SEL 1.064 1.071 1.048 1.043 1.064 1.032 1.009 0.994 1.028 1.038 0.000
5L94 CBK-LGN 1.065 1.073 1.054 1.047 1.068 1.043 1.015 1.001 1.023 1.045 0.000
Report No. T&S Planning – 2013-058 Page 34
Not to be reproduced without the permission of BC Hydro
HW Case 3 – 1200 MW BC to AB
Cont. Name NIC 500 ACK 500 SEL 500 SEL 230 VAS 500 CBK 500 CBK 230 NTL 230 NTL 138 NLY 230
LNGDN 500
[50703] [50702] [50792] [50783] [51134] [50791] [50782] [50787] [50776] [50784] [54158]
Pre Contingency 1.043 1.048 1.015 1.017 1.035 0.950 0.933 0.913 1.024 1.019 1.007
SEL T1 1.043 1.047 1.013 1.015 1.034 0.948 0.930 0.911 1.023 1.018 1.007
SEL T2&T3 1.043 1.047 1.011 1.014 1.033 0.947 0.930 0.909 1.030 1.017 1.007
CBK T2&T6 1.043 1.047 1.014 1.016 1.034 0.945 0.928 0.907 1.029 1.018 1.006
5L71 MCA-NIC 1.018 1.032 1.007 1.012 1.016 0.943 0.927 0.906 1.028 1.016 1.005
5L75 REV-ACK 1.038 1.036 1.011 1.015 1.030 0.946 0.930 0.910 1.022 1.018 1.006
5L76 ACK-NIC 1.032 1.038 1.009 1.014 1.025 0.944 0.928 0.907 1.028 1.017 1.005
5L81 NIC-ING 1.030 1.041 1.011 1.015 1.026 0.942 0.926 0.905 1.027 1.017 1.004
5L82 NIC-MDN 1.029 1.040 1.010 1.015 1.025 0.942 0.927 0.906 1.028 1.017 1.004
5L87 NIC-KLY 1.026 1.039 1.010 1.014 1.024 0.944 0.928 0.907 1.029 1.017 1.006
5L91 ACK-SEL 1.043 1.051 0.993 1.003 1.025 0.932 0.917 0.896 1.029 1.010 1.003
5L96 VAS-SEL 1.040 1.043 1.007 1.012 1.033 0.939 0.924 0.903 1.025 1.015 1.004
5L98 NIC-VAS 1.040 1.045 1.007 1.012 1.007 0.942 0.927 0.906 1.028 1.016 1.005
2L112 NLY-BDY 1.046 1.050 1.019 1.020 1.040 0.958 0.942 0.920 1.030 1.015 1.011
2L221 SEV-SEL 1.040 1.043 1.015 1.017 1.034 0.951 0.934 0.914 1.025 1.019 1.008
2L277 WAN-NLY 1.042 1.047 1.011 1.012 1.032 0.946 0.929 0.910 1.022 1.011 1.006
2L288 KCL-BTS 1.043 1.047 1.014 1.016 1.034 0.949 0.932 0.912 1.024 1.019 1.007
2L289 SEL-BTS 1.042 1.047 1.012 1.013 1.033 0.947 0.930 0.911 1.023 1.016 1.007
2L293 SEL-NLY 1.044 1.048 1.017 1.018 1.036 0.951 0.932 0.912 1.024 1.020 1.008
2L294 CBK-NLY 1.042 1.046 1.006 1.012 1.030 0.928 0.915 0.895 1.028 1.025 1.003
2L295 SEL-KCL 1.043 1.047 1.012 1.013 1.034 0.947 0.930 0.911 1.023 1.017 1.007
1L274 NTL-POCATER 1.044 1.049 1.019 1.020 1.037 0.962 0.949 0.958 1.024 1.022 1.010
1L275 NTL-COLEMAN 1.043 1.047 1.014 1.016 1.034 0.945 0.929 0.912 1.034 1.019 1.004
5L92 CBK-SEL 1.051 1.055 1.034 1.029 1.039 1.032 1.009 0.994 1.029 1.031 0.000
5L94 CBK-LGN 1.053 1.056 1.042 1.034 1.045 1.040 1.019 1.005 1.027 1.038 0.000
Report No. T&S Planning – 2013-058 Page 35
Not to be reproduced without the permission of BC Hydro
HW Case 3b – 1200 MW BC to AB
Cont. Name NIC 500 ACK 500 SEL 500 SEL 230 VAS 500 CBK 500 CBK 230 NTL 230 NTL 138 NLY 230
LNGDN 500
[50703] [50702] [50792] [50783] [51134] [50791] [50782] [50787] [50776] [50784] [54158]
Pre Contingency 1.055 1.065 1.027 1.027 1.050 0.961 0.945 0.925 1.033 1.025 1.009
SEL T1 1.055 1.065 1.026 1.026 1.050 0.961 0.945 0.925 1.033 1.025 1.009
SEL T2&T3 1.055 1.065 1.026 1.026 1.050 0.960 0.945 0.925 1.033 1.025 1.009
CBK T2&T6 1.055 1.065 1.025 1.026 1.050 0.955 0.941 0.923 1.031 1.025 1.008
5L71 MCA-NIC 1.034 1.052 1.019 1.022 1.035 0.954 0.939 0.920 1.029 1.022 1.008
5L75 REV-ACK 1.053 1.060 1.025 1.026 1.048 0.959 0.944 0.924 1.032 1.025 1.009
5L76 ACK-NIC 1.046 1.059 1.022 1.024 1.044 0.957 0.942 0.922 1.030 1.024 1.008
5L81 NIC-ING 1.046 1.060 1.022 1.024 1.043 0.954 0.940 0.920 1.029 1.024 1.007
5L82 NIC-MDN 1.044 1.059 1.022 1.024 1.042 0.954 0.939 0.920 1.029 1.023 1.007
5L87 NIC-KLY 1.049 1.062 1.025 1.026 1.046 0.959 0.944 0.924 1.032 1.025 1.009
5L91 ACK-SEL 1.050 1.066 0.998 1.007 1.032 0.942 0.928 0.909 1.029 1.012 1.007
5L96 VAS-SEL 1.055 1.064 1.018 1.021 1.051 0.954 0.939 0.920 1.029 1.022 1.008
5L98 NIC-VAS 1.051 1.061 1.016 1.020 1.022 0.954 0.939 0.921 1.029 1.021 1.009
2L112 NLY-BDY 1.055 1.065 1.027 1.028 1.050 0.966 0.951 0.930 1.037 1.022 1.012
2L221 SEV-SEL 1.054 1.064 1.025 1.026 1.049 0.960 0.945 0.925 1.033 1.025 1.010
2L277 WAN-NLY 1.054 1.064 1.023 1.024 1.048 0.958 0.943 0.923 1.031 1.019 1.009
2L288 KCL-BTS 1.055 1.065 1.026 1.026 1.050 0.960 0.945 0.925 1.033 1.025 1.009
2L289 SEL-BTS 1.055 1.065 1.025 1.025 1.050 0.959 0.944 0.924 1.032 1.024 1.009
2L293 SEL-NLY 1.055 1.066 1.028 1.029 1.051 0.961 0.943 0.924 1.032 1.020 1.010
2L294 CBK-NLY 1.053 1.063 1.018 1.022 1.046 0.940 0.928 0.910 1.029 1.031 1.006
2L295 SEL-KCL 1.055 1.065 1.025 1.025 1.050 0.959 0.944 0.924 1.032 1.024 1.009
1L274 NTL-POCATER 1.056 1.067 1.031 1.030 1.053 0.974 0.962 0.973 1.025 1.029 1.012
1L275 NTL-COLEMAN 1.054 1.065 1.025 1.026 1.050 0.957 0.942 0.926 1.023 1.025 1.007
5L92 CBK-SEL 1.070 1.078 1.050 1.043 1.068 1.034 1.011 0.996 1.031 1.039 0.000
5L94 CBK-LGN 1.071 1.080 1.057 1.048 1.073 1.050 1.027 1.012 1.034 1.047 0.000
Report No. T&S Planning – 2013-058 Page 36
Not to be reproduced without the permission of BC Hydro
APPENDIX D – TRANSIENT STABILITY PERFORMANCE PLOTS
Selected transient stability response to single contingencies listed in Appendix B and as listed in
Tables 4-4 and 4-8 are displayed below.
Report No. T&S Planning – 2013-058 Page 37
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hs_case3a (BC-AB = 1200MW)
Bus Variables 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 38
Not to be reproduced without the permission of BC Hydro
Line Power Flows 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 39
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 13 -- 5L92 CBK-SEL 3PH@CBK 500KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 40
Not to be reproduced without the permission of BC Hydro
Bus Variables 13 -- 5L92 CBK-SEL 3PH@CBK 500KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 41
Not to be reproduced without the permission of BC Hydro
Line Power Flows 13 -- 5L92 CBK-SEL 3PH@CBK 500KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 42
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 33 -- 2L294 CBK-NLY 3PH@CBK 230KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 43
Not to be reproduced without the permission of BC Hydro
Bus Variables 33 -- 2L294 CBK-NLY 3PH@CBK 230KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 44
Not to be reproduced without the permission of BC Hydro
Line Power Flows 33 -- 2L294 CBK-NLY 3PH@CBK 230KV 13hs_case3a (BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 45
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case2a(BC-AB = 1100MW)
Report No. T&S Planning – 2013-058 Page 46
Not to be reproduced without the permission of BC Hydro
Bus Variables 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case2a(BC-AB = 1100MW)
Report No. T&S Planning – 2013-058 Page 47
Not to be reproduced without the permission of BC Hydro
Line Power Flows 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case2a(BC-AB = 1100MW)
Report No. T&S Planning – 2013-058 Page 48
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case3(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 49
Not to be reproduced without the permission of BC Hydro
Bus Variables 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case3(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 50
Not to be reproduced without the permission of BC Hydro
Line Power Flows 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case3(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 51
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 52
Not to be reproduced without the permission of BC Hydro
Bus Variables 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 53
Not to be reproduced without the permission of BC Hydro
Line Power Flows 12 -- 5L91 ACK-SEL_2 3PH@SEL 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 54
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 13 -- 5L92 CBK-SEL 3PH@CBK 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 55
Not to be reproduced without the permission of BC Hydro
Bus Variables 13 -- 5L92 CBK-SEL 3PH@CBK 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 56
Not to be reproduced without the permission of BC Hydro
Line Power Flows 13 -- 5L92 CBK-SEL 3PH@CBK 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 57
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 15 -- 5L94 CBK-LGN 3PH@CBK 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 58
Not to be reproduced without the permission of BC Hydro
Bus Variables 15 -- 5L94 CBK-LGN 3PH@CBK 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 59
Not to be reproduced without the permission of BC Hydro
Line Power Flows 15 -- 5L94 CBK-LGN 3PH@CBK 500KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 60
Not to be reproduced without the permission of BC Hydro
Generator MW Outputs 33 -- 2L294 CBK-NLY 3PH@CBK 230KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 61
Not to be reproduced without the permission of BC Hydro
Bus Variables 33 -- 2L294 CBK-NLY 3PH@CBK 230KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 62
Not to be reproduced without the permission of BC Hydro
Line Power Flows 33 -- 2L294 CBK-NLY 3PH@CBK 230KV 13hw2ae_case3b(BC-AB = 1200MW)
Report No. T&S Planning – 2013-058 Page 63
Not to be reproduced without the permission of BC Hydro
Report No. T&S Planning – 2013-058 Page 64
Not to be reproduced without the permission of BC Hydro
END OF REPORT