Industrial and Commercial Power SystemsTopic 2

SWITCHBOARDS

The University of New South Wales

School of Electrical Engineeringand Telecommunications

Overview

Also called “Switchgear and Controlgear Assembly” (SCA)

Generally, may need both a main HV switchboard and one or more LV SWBs

Purpose: take power from main supply source and distribute to various circuits within building.

Metering Proper control of power flow Protection against damaging effects of faults.

Overview SWB design requirements:

protection is necessary to prevent personnel hazards and also equipment hazards and possible fires.

to present no danger of electric shock or injury to personnel in vicinity during normal or abnormal operation.

Explosions in switchboards are a not infrequent occurrence which can cause significant injury to personnel.

In many cases, work is performed on switchboard components while they are still live.

What are the components in a typical domestic switchboard ?

Switchgear enclosures and housings

Open-type Dead-front

Examples of switchboard assemblies, AS 3439.1-2002

LV assembliesModular distribution board

Parts of a switchboard

Incoming cablesOutgoing circuit conductors Internal busbarsMain isolating switches or section switchesCircuit breakersHRC fuses and CFS units Protection relaysMetering equipmentOvervoltage surge protection

Parts of a switchboard

Incoming cables

either HV or MV/LV

HV cables:

impregnated paper insulation (unlikely these days)

cross linked polyethylene (XLPE), most common

ethylene propylene rubber (EPR) – more flexible

LV cables: XLPE or EPR type

Parts of a switchboard

Outgoing circuit conductors

These may be of following types:

Insulated cables Insulated busbars Busbar trunking systems Mineral Insulated Metal-Sheathed (MIMS) cables Fire-resistant cables

Mineral Insulated Metal-Sheathed (MIMS) cables

Standard features and advantages of MIMS cables are: High Insulation Resistance Conductor / Sheath and Conductor / Conductor.

Long Life.

Easy Installation

Mechanical Strength

Safety

Rapid Response

Dielectric Strength

Radiation Resistance

Corrosion and Scaling Resistance

Long Lengths

Small Cable Diameter

Parts of a switchboard

Internal busbars

Rigid copper (or aluminium) bars (insulated or uninsulated) in large SWBs or simply insulated single phase cables in small SWBs.

Bare LV busbars are close together and are subject to high forces on short circuit. This and resonant force effect must be considered in determining supports.

Parts of a switchboard Main isolating switch or section switches

These allow segregation of switchboard or its component parts to allow maintenance work on SWB.

Parts of a switchboard

Circuit breakersHV or LV depending on switchboard voltage level.

HV C/B types are oil, SF6 and vacuum units, contained in withdrawable rack-mounted carriers. Oil C/Bs no longer used in new installations.

LV/MV (<1000 V) C/Bs are air-break type. Large MV CB units may be also rack-mounted but modern SWB will have moulded-case circuit breakers (MCCBs) for higher current ratings (> 100 A) and miniature circuit breakers (MCBs) for lower rating (< 100 A). MCBs normally used in smaller sub-main and local SWBs in a building.

ABB SF6 C/Bwithdrawable parts

Moulded case LV circuit breakers of varying ratings

e.g. Eaton Cutler-Hammer series G: ratings up to 2500A with interrupting capacities up to 200kA at 240V.

Parts of a switchboard

HRC fuses and CFS units

These are also used in MV and LV switchboards for high level fault protection and, in many cases, there are combinations of HRC (high rupturing capacity) fuses and overload switches with limited interrupting capacity used (combined fuse-switch or CFS units) because of their economy.

Fuse breaking capacity:

Is maximum current that can safely be interrupted by the fuse,

Is potential maximum current the fuse can withstand without shattering.

Generally should be higher than maximum prospective short circuit current.

There are two types of fuses: High Blow Current (HBC) Low Blow Current (LBC)

High Blow Current (HBC) HBC fuses (or HRC High Rupture Current) are generally defined as being able

to withstand more than 10 times their rated current without shattering.

Some low-voltage current-limiting HRC fuses rated for 300kA.

Fuses for high-voltage equipment, up to 115kV, are rated by the total apparent power (megavolt-amperes, MVA) of the fault level on circuit.

They typically have a ceramic body and are filled with sand.

HBC fuses are designated "H".

Low Blow Current (LBC) LBC fuses on the other hand are designed for situations where maximum fault

current is likely to be less than 10 times the rated fuse current. Fuses for small low-voltage wiring systems are commonly rated to interrupt

10kA. They typically have a glass body in which fuse wire can clearly be seen, making

it very easy to see if the fuse has blown. LBC fuses are designated "L”

Parts of a switchboard

Protection relays

Used for higher voltages, together with associated instrument transformers [current transformers (CTs) and voltage transformers (VTs)].

Overcurrent protection units are used to activate timing relays so as to provide proper fault protection operation.

At lower voltages, circuit breakers normally have in-built fault detection sensing, thus no separate relaying is required.

Parts of a switchboard

Metering equipment

The metering of SWB will include:

line and phase voltage, line current in each phase, total power, power factor metering.

Parts of a switchboard

Over-voltage surge protection

Modern switchboards will also have some over-voltage surge protection designed into both HV and LV sides to protect equipment against effects of any over-voltage transients that may be generated within the system or conducted in from external sources.

Switchgear & busbar requirements

Life of 25-30 years at least Spare capacity for expansion (20-40%). Good quality and reliable switchgear in various outgoing

functional units. Proper protection design, particularly in time discrimination

with flexible variation of I-t characteristics possible. Adequate interrupting capacity for future expansion Residual current (earth leakage) protection Adequate current carrying capacity Protection against ingress of contamination Adequate compartmentalization to limit arc faults

Specifications Purchaser should specify:

Voltage, power, current ratings. Specific rating for each C/B and busbar system Required fault level and protection operating time. Internal structure, segregation of compartments International Protection (IP) numbers for protection against

dust and moisture Arc containment requirements Earthing requirements Electrodynamic forces and insulator mechanical strength

requirements. Thermal features - maximum temperature rises etc. Testing requirements (Type tests and Routine tests).

Electrical characteristics

Rated operational voltage

Rated insulation voltage

Rated impulse withstand voltage

Rated current

Rated short-time current (1s)

Rated peak withstand current

Rated conditional short-circuit current

Rated fused short-circuit current

Rated diversity factor

Rated operational voltage: stated as voltage between phases, e.g. 400V

Rated insulation voltage: voltage to which dielectric test voltages are referred. Shall not exceed rated operational voltage.

Rated impulse withstand voltage: peak value of impulse voltage the assembly is able to withstand without failure

Rated current: current that can carry without temperature rise of various parts exceed limit

Rated short-time current:

Rated conditional short-circuit current: value of prospective short-circuit current that circuit with protection device can withstand satisfactorily.

Rated fused short-circuit current: is rated conditional short-circuit current when protective device is a fuse

Rated diversity factor: ratio of maximum sum of assumed currents of all main circuits to sum of rated currents of all main circuits. If not available, assume factor of 0.9 for 2-3 main circuits, 0.8 for 4-5 main circuits, 0.7 for 6-9, and 0.6 for 10 or more.

Standard specifications

AS3439.1-2002 Low Voltage Switchgear and Controlgear Assemblies – Part 1: Type-tested and partially type-tested assemblies

AS/NZS 3439.2:2002 - Particular requirements for busbar trunking systems (busways)

AS/NZS 3439.3:2002 - Particular requirements for low-voltage switchgear and controlgear assemblies intended to be installed in places where unskilled persons have access for their use - Distribution boards (IEC 60439-3:1990, MOD)

AS 2067-2008 - Substations and high voltage installations exceeding 1 kV a.c.

Ingress Protection: IP number

Must protect against:

ingress of various contaminants (e.g. particles, dust and moisture)

access by personnel to live internal parts

IP number uses two numerals to represent specific design requirements to prevent ingress:

1st numeral = degree of protection against ingress of solid objects and thus protection of personnel against access to hazardous parts.

2nd numeral = degree of protection against harmful ingress of water.

additional letter (optional) = degree of protection of personnel against access to hazardous parts

supplementary letter (optional) = other information

Ref: HB300-2001

IP00 = completely open, no protection IP68 = hermetically sealed enclosure IP21 typical for commercial buildings IP65 for industrial manufacturing or outdoor SWBs

Electrical installations at UNSW: IP??

IP43 for interior

IP56 for exterior

Arc Fault Containment Arcing: caused by insulation failure such as

ageing, moisture, solid particle contamination, etcDifficult to predict value of arc voltage. Arcing involves significant energy and thus

damage is very destructive Segregation of internal parts limits spreading of

damage IEEE 1584-2002 provides method to calculate

incident energy and arc-flash protection boundaries.

http://www.nilsen.com.au/

NILSEN designs tested to 100kA (at 440V) prospective and 6.6kV to 18kA prospective

Purpose of specifying internal arcing fault containment is to:

provide a measure of operator protection restrict damage resulting from arc fault to the functional unit involved so that supply can be reinstated with minimum outage

Internal segregation of circuits

SWBs have many internal components, thus

susceptible to faults.

High impedance arcing fault is a major problem.

Segregate chambers will assist in containing faults.

Switchboard compartment

forms of segregation

enclosure busbar

internalseparation

functionalunit

terminals

Fig. D2 AS3439.1:2002

Switchboard Design

Insulation DesignThermal DesignProtection against electric shockTesting of Switchboards

Switchboard Design

Insulation DesignPower frequency insulation level Lightning impulse insulation level (BIL)Creepage distance (surface tracking)

Thermal DesignProtection against electric shockTesting of Switchboards

(a) for main circuit

(b) for auxiliary circuits AS3439.1:2002

Table G1 AS3439.1:2002

Creepage distances and clearances

Case 1: creepage distance and clearance are measured directly across the groove.Case 2: clearance is line-of-sight distance, creepage path follows contour of groove.

Pollution degree

Pollution degree 1: no pollution or non-conductive pollution

Pollution degree 2: non-conductive pollution, temporary conductive when condensation occurs.

Pollution degree 3: conductive pollution or non-conductive pollution becomes conductive due to condensation

Pollution degree 4: persistently conductive

Presenter

Presentation Notes

6kV for homogeneous: 3kV/mm breakdown strength in air. For inhomogenous, increase clearance of 5.5mm

Switchboard Design

Insulation DesignThermal DesignProtection against electric shockTesting of Switchboards

Table 2 AS3439.1:2000

Switchboard Design

Insulation DesignThermal DesignProtection against electric shockTesting of Switchboards

Protection against direct contact

Protection by insulation of live parts

Protection by barriers or enclosures

Protection against indirect contact

Protection by using protective circuits

Protection by other measures (electrical separation of

circuits, total insulation)

Proper earthing of switchboard

System earthing

Three types:

TN systems

TT systems

IT systems

T (terra): direct connection of one point of supply system to earth

I (insulation): all live parts of supply isolated from earth or one point connected to earth through an impedance

1st letter (I or T) gives relationship of supply to earth

T (terra): direct connection of exposed conductive parts to earth, independent of earthing of supply system

N (neutral): direct connection of exposed conductive parts to earthed point of supply (neutral point).

2nd letter (T or N) gives relationship of exposed conductive parts of the general installation to earth

TN systems: one point directly earthed, exposed conductive parts connected to that point by protective conductor (PE)

TN-S system: separate neutral (N) and PE throughout TN-C system: N and PE combined into a single

conductor throughout TN-C-S system: N and PE combined into a single

conductor in a part of the system

TN-S

TN-C

TN-C-S

TT system: one point directly earthed, exposed conductive parts connected to earth via separate earth electrode no direct connection between live parts and earth, exposed conductive parts connected to earth

IT system: no direct connection between live parts and earth, exposed conductive parts connected to earth

Switchboard Design Insulation Design Thermal Design Protection against electric shock Testing of Switchboards

Two test categories: Type Tests: done only on one unit representative of

the design Routine Tests: done on every manufactured unit

Testing laboratories in Sydney Testing and Certification Australia (TCA) TestSafe Australia (associated with NSW WorkCover)

Lane Cove Testing Station (LCTS) is Australia's internationally recognized high power test facility. E.g test LV switchboard max 160kA for 1s; HV switchgear 11kV, max 26kA short-circuit making or breaking

UNSW HV Electrical Services

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