This document is a test report from Advanced Power Analytics Limited summarizing HV installation and testing at an Onyx Group data center in Edinburgh. Various high voltage terminations, switchgear, transformers, and busbars were subjected to insulation resistance testing, high voltage pressure testing between 18-25kV, secondary current injections, and ductor current testing. The report provides an overview of the testing procedures and results, and recommends further protection studies, thermal imaging, and planned maintenance to ensure system resilience.
Tutorial on Distance and Over Current ProtectionSARAVANAN A
Contents
• Protection Philosophy of ERPC
• Computation of Distance Relay Setting
• System Study to Understand Distance Relay
Behaviour
• DOC and DEF for EHV system
Tutorial on Distance and Over Current ProtectionSARAVANAN A
Contents
• Protection Philosophy of ERPC
• Computation of Distance Relay Setting
• System Study to Understand Distance Relay
Behaviour
• DOC and DEF for EHV system
Differential Amplifiers in Bioimpedance Measurement Systems: A Comparison Bas...IDES Editor
In this paper we have analysed the Common Mode
Rejection Ratio (CMRR) for differential amplifiers used in
bioimpedance measurement systems and derived the complete
equations for the case when OPAMPs have finite differential
and common mode gains. In principle, passive ac-coupling
networks that include no grounded components have an
infinite CMRR, but they must provide a path for input bias
currents. The paper provides a novel approach as to how
component tolerances limit the CMRR and affect the transient
response of different networks. Experimental results and
various measurements support our theoretical predictions.
The best CMRR is obtained when the differential gain is
concentrated in the input stage, but it decreases at frequencies
above 1 kHz because of the reduced CMRR for the differential
stage at these frequencies.
A Low Phase Noise CMOS Quadrature Voltage Control Oscillator Using Clock Gate...IJERA Editor
This project presents the low phase noise cmos quadrature voltage control oscillator using clock gating technique. Here the colpitts vco is used to split the capacitance in the Qvco circuit producing quadrature output. The startup condition in the oscillator is improved by using 퐺푚enhancement [12].This QVCO performs the operation anti phase injection locking fordevice reuse [8]. The new clock gating technique is used to reduce the power with thepower supply 1.5v. The QVCO uses a 0.5m퐴with phase error of 0.4표and exhibits a phase noise of -118dBc/HZ at 1MHZ offset at the centre frequency of 500MHZ.
Index terms: current switching, clock gating, phase noise, Qvco
Differential Amplifiers in Bioimpedance Measurement Systems: A Comparison Bas...IDES Editor
In this paper we have analysed the Common Mode
Rejection Ratio (CMRR) for differential amplifiers used in
bioimpedance measurement systems and derived the complete
equations for the case when OPAMPs have finite differential
and common mode gains. In principle, passive ac-coupling
networks that include no grounded components have an
infinite CMRR, but they must provide a path for input bias
currents. The paper provides a novel approach as to how
component tolerances limit the CMRR and affect the transient
response of different networks. Experimental results and
various measurements support our theoretical predictions.
The best CMRR is obtained when the differential gain is
concentrated in the input stage, but it decreases at frequencies
above 1 kHz because of the reduced CMRR for the differential
stage at these frequencies.
A Low Phase Noise CMOS Quadrature Voltage Control Oscillator Using Clock Gate...IJERA Editor
This project presents the low phase noise cmos quadrature voltage control oscillator using clock gating technique. Here the colpitts vco is used to split the capacitance in the Qvco circuit producing quadrature output. The startup condition in the oscillator is improved by using 퐺푚enhancement [12].This QVCO performs the operation anti phase injection locking fordevice reuse [8]. The new clock gating technique is used to reduce the power with thepower supply 1.5v. The QVCO uses a 0.5m퐴with phase error of 0.4표and exhibits a phase noise of -118dBc/HZ at 1MHZ offset at the centre frequency of 500MHZ.
Index terms: current switching, clock gating, phase noise, Qvco
Test done on Power transformers.
Insulation Resistance test, Winding Resistance test, Ratio Measurements, Magnetic balance test, Tan delta test, DIssolved gas analysis for transformer, Sweep frequency response analysis.
Module 2 ee369 KTU syllabus-high voltage ac generation,resonant circuitsAsha Anu Kurian
Generation of high AC voltages-Testing transformer – single unit testing transformer, cascaded transformer – equivalent circuit of cascaded transformer – generation of high frequency AC voltages- series resonance circuit – resonant transformer – voltage regulation.
1. ADVANCED POWER ANALYTICS LIMITED
Onyx Group - HV installation Test Report
Client - Onyx
Document Prepared by - Ron Richardson (On behalf of Keysource)
Document Date - 02/05/2012
4. The following report has been produced to help give clear indication of the testing procedures and the respective results of the tests that were necessary for
the successful implementation of the new HV Substation which has been installed at the Onyx Group data centre (Edinburgh)
Switchgear & Transformer Testing:
Due to the existing configuration (RMU ‘close-coupled’ to the Transformer) in order to carry out the testing of the Transformer it would be necessary to
disconnect the ‘new’ previously installed HV termination at the RMU and then use the switching ‘on’ positions to test through the switches onto the HV
windings of the Transformer. The HV test voltage values and durations would then have to be considered to ensure no possibility of ‘Over-stressing the HV
Equipment. Functional Switching Checks were also carried out to confirm Switching operation reliability.
Secondary protection tests were also carried out to check that the Switchgear would operate under fault conditions as well as Insulation resistance checks for
the Current Transformers
Method Statements and Risk assessments were constructed prior to the work commencing highlighting the Process and Immediate risk(s) in connection with
the tasks.
The equipment tested was subjected to the following electrical tests consisting of :
1 - Pre and post Insulation resistance testing @ 5KV
2 - Uni-polar HV Testing @ 18 - 25KV (for 1 min & 15min durations)
3 - Secondary Injections Currents (0 - 20 amps) for Trip Testing Simulations
4 - Ductor testing Currents (50 & 100 amps) for testing the HV Busbars
*Important Notes -
1 - Any recorded values lower than 75 Mega Ohms for Transformer tests will need to be reported to the manufacturer prior to any Energization activity as this
may representative of a potential Failure.
2 - Any HV Cables tests with Insulation resistance values lower than 500 Mega Ohms prior to Energization will be subject to further investigation works as this
may again be representative of imminent or possible near future Failure.
15. 3.3.1 - HV Pressure Testing Theory (25 KV)
System Voltage Peak Value
This figure is the system voltage, and This figure is 2x the RMS value and is used
is the phase to phase value that the to theoretically simulate some of the 'in rush
cable/switchgear is subjected to currents that are associated at the point of
energisation.
Nominal voltage
This figure takes is the nominal
11000 x 1.414 x 2.55 x 1.1 voltage based on 10% more than
√3 the system voltage (11 KV)
Root 3 Transient Voltage Additional notes (For new cables)
This figure is used to establish the voltage in This figure takes into consideration 1 - Insulation resistance test results should be greater than 10
any individual 'phase the transient voltage at the peak of gig ohms when testing each individual core to earth as well as
Value = 1.732 the sinewave phase to phase testing.
2 - Insulation resistance tests that are less than 10 gig Ohms will
result in further inspection of the cable installation for any
possible causes.
11000 x 1.414 x 2.55 x 1.1 3 - If there is a large variation in core test results when carrying
out insulation resistance tests then further investigation will be
1.732 required.
6351 x 1.414 x 2.55 x 1.1
Test value = 25 KV
25185 volts
(Per Phase - DC Test)
16. 3.3.2 - HV Pressure Testing Theory (18 KV)
Cable test theory Additional notes (For new cables)
Due to the nature of the installation it is deemed that the cable under test is an 'old' cable 1 - Insulation resistance test results should be greater than 10
because it would have been subjected to factory tests. The test value used in this instance is a gig ohms when testing each individual core to earth as well as
value that takes this into consideration as well as the fact that there will be certain impulse phase to phase testing.
values which can be 2 or 3 times the Peak value. Each phase of the cable will be tested 2 - Insulation resistance tests that are less than 10 gig Ohms will
individually with the other phases earthed for a duration of 1 min. This test will be a DC Test. result in further inspection of the cable installation for any
possible causes.
3 - If there is a large variation in core test results when carrying
out insulation resistance tests then further investigation will be
Peak Value
System Voltage required.
This figure is 2x the RMS value and is used
This figure is the system voltage, and
to theoretically simulate some of the 'in rush
is the phase to phase value that the
currents that are associated at the point of
cable/switchgear is subjected to
energisation.
11000 x 1.414 x 2
√3
Peak multiple factor
Root 3 This figure takes into consideration
This figure is used to establish the voltage in the peak value which can be 2 or 3 x
any individual 'phase the peak value when the cable is
Value = 1.732 energised
11000
x 1.414 x 2
1.732
Test value = 18 KV
6351 x 1.414 x 2
(Per Phase - DC Test)
17960 volts
20. The following items listed below are recommended future works that we feel are necessary to ensure the system resilience for the current and future power
demands the Data centre will be subjected to:
1 - Full HV/LV Protection Study:
It is recommended that a full Protection study including the current and future HV equipment is carried out so that the data centre can run with the maximum
level of safety.
2 - Thermal imaging of new and existing infrastructure:
Thermal imaging will help gauge an understanding of the system performance with respect to system efficiencies and help identify equipment which emit
excessive heat which equate to power losses.
3 - Detailed Power Supply Audit (HV &LV):
APA Ltd can conduct a detailed power audit which differs from the conventional approach in that:
a) We will identify the losses within the system using multiple approaches.
b) We will identify how the problems (if any) came into existence.
c) We will accurately determine what the costs of the inefficiencies are with respect to money.
d) Provide realistic tangible solutions for the client starting with looking at ways to re-managing the existing power infrastructure.
4 - Asset Maintenance:
We recommend that a planned maintenance program is constructed with respect to the HV supply and Heavy current LV equipment which can be factored in at
the most convenient times suitable to the client.
21. Advanced Power Analytics Limited
Installation Services:
HV & LV Cable Jointing up to 33 KV
HV & LV Construction Up to 33 KV
Protection Testing / Grading Surveys
Full HV and LV Commissioning
Maintenance & Analysis (Online & Offline)
HV & LV Maintenance Up to 132 KV
Power Quality Analysis / Power Auditing
Thermal Imaging
Ultrasonic Testing
Partial Discharge Testing
Additional Services:
Technical Consultancy
Technical Media Development
Asset Management
Project Management
Training (On site and system specific)
No.8 Bank Apartments, Marlow, Buckinghamshire, United Kingdom SL7 3DX
Mobile - +44 7515 384458
email - theronrichardson@live.com