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Wednesday, 7 January 2015

Main Consumer Units

Fired-up over consumer units

A number of fire investigators throughout the UK have noticed a recent trend with an increasing number of fires involving plastic consumer units.

Figure 1: A consumer unit located under the stairs in a terraced three-storey house
In the last five years, the Glasgow Fire Brigade has investigated 107 fires (October 2006 to October 2011), and in the last 12 months it has identified a 100% increase in these incidents, with 45 investigations concluding that the fire originated within a plastic consumer unit. 

There are several types of fault that lead to the ignition of the plastic enclosure/casing. The most common is localised resistance heating at the connection of the neutral link (solid or flexible) terminal connection bar. These conductors are used to connect the main isolation switch and the neutral connection/terminal bar. Other areas where a neutral connection fault can occur are additional neutral conductor links to connect other components (such as the conductor linking the main neutral connection terminal bar to the Residual Current Device (RCD[s]).

In general, electrical installation contractors may perceive neutral connections as less hazardous than the live connections. However, in a single-phase consumer unit the total current for the final circuits is flowing through the main neutral connections, which are just as susceptible to poor connections as the live connections. Other locations of defective connections that have resulted in the ignition of a plastic consumer unit are the connections at the input or output of a main isolator switch or the connections of an RCD.

What are the problems that lead to these defective connections? 

Poor workmanship by the installer is a one factor. The use of inappropriate tools, distraction when making final connections, not re-checking connections (particularly on larger conductors) or not checking the tightness of factory made connections can all lead to localised resistance heating. 

The actual construction of the connections by the manufacturer is another potential issue. Indeed, Nick Carey has noticed a significant change in the construction of connections/terminations within consumer units over the last 10 to 15 years. 
The use of one fixing screw per connection instead of two screws, the use of plated steel fixing screws instead of brass screws, quality issues with threads and quality issues with burrs of metal at the end of screws that limit the conductor/screw contact area. There has also been a change from rigid plastics to more aesthetically pleasing moulded plastic enclosures. 

The change with enclosure construction has also coincided with a product that electricians find easier and quicker to install, with soft plastic openings that are simple to remove and adapt for cable entry points.
Figure 2: Typical fire damage to the enclosure of a plastic consumer unit in a fire confined to the under stairs cupboard of a two storey house
Another more recent problem affecting several brands of consumer unit is a manufacturing defect within Miniature Circuit Breakers (MCBs) leading to resistance heating at the switching contacts area.
What are effects of these fires? 

The changes to the type of plastics used to construct consumer unit enclosures in the last 10-15 years and pressures on manufacturers to be environmentally friendly has led to a reduction or even an omission of fire retardants in the plastic used to construct the enclosures.

The results of fire investigations where physical evidence has identified the fire originating within a plastic consumer unit is that defective connections have led to the ignition and destruction of the plastic enclosures. The fire often develops to involve the entire plastic enclosure with burning droplets of plastic falling to the floor that on occasions can start secondary fires below. Other items stored or installed adjacent to the consumer units determine how the fire develops from this point. Some of the fires have also involved gas pipes, which has significantly increased the fire development. 

The fires have also injured a number of occupiers. Typically the injuries are smoke inhalation but there have been some burn injuries. Fortunately, to date, there have not been any recorded fatalities. However, there have been a number of near misses with the fire service rescuing occupiers trapped by the fire within their properties.
In one recent case, the consumer unit was located under the stairs in a terraced three-storey house (as shown in figure 1). The quantity of storage within the cupboard and the involvement of the timber staircase ensured the fire spread to the top floor. The fire was discovered by one of the occupiers at 1am and the other nine occupants were quickly alerted to the fire and they all successfully evacuated. The damage to the consumer unit was so extensive that it was not possible to identify the product brand.

Fires involving plastic consumer units often only leave the remains of the main switch, RCDs and MCBs with the remains suspended by the final circuit conductors. The plastics used in the casings of the main switch, RCDs and MCBs contain flame-retardants and are designed to withstand significantly higher temperatures than the plastics used in the enclosures. 

Smoke being produced by the fire began to overwhelm the dedicated extraction system of the test facility
Figure 2 details the typical fire damage to the enclosure of a plastic consumer unit in a fire confined to the under stairs cupboard of a two storey house.

Ignition tests

A recent series of ignition tests was undertaken on five brands of plastic consumer units. The tests were initiated by the Glasgow Fire Brigade and undertaken with the collaboration of Bureau Veritas Solutions and the Electrical Safety Council. Initial tests identified that three of the five plastic enclosures did not use a flame retardant in the plastic. The other two brands used enclosures with a flame retardant incorporated in the plastic.

The first series of tests were confined to replicating the hot wire material test as specified in BS/EN 60947-1: 2007 + A1:2011. Criticism could be raised by the manufactures of consumer units as BS/EN 60947 is not a ‘product test’. However, the test successfully identified the ease in which the plastics used in the construction of the enclosures were ignited. A pre-conditioned hot wire is wrapped around a plastic sample and the wire is then energised with prescriptive electrical limits for up to 30 seconds. In these tests a maximum wire temperature of 550°C was measured.

The results of the hot wire tests were that with the exception of one sample of plastic that had a flame retardant, all of the plastic samples ignited irrespective of whether they did or did not have a flame retardant incorporated in the plastic. The shortest time to flaming ignition was 11 seconds for a plastic sample without a flame retardant and 16 seconds for a plastic sample with a flame retardant. 

All five plastic consumer unit enclosures were subjected to a needle flame test in accordance with the EN 60695-11-5:2005 standard. The needle flame was introduced into the consumer unit via a small opening to enable access to the main neutral connection at the neutral connection bar.

One of the consumer units with a flame retardant did not ignite and the flame was applied at four additional areas, again without ignition. The second consumer unit with a flame retardant ignited and once the needle flame was removed, the flame self-extinguished within eight seconds. 

The remaining three consumer unit ignition tests resulted in fires that spread from the initial needle flame to involve the entire plastic enclosure. The shortest time from needle flame application to the ignition of the plastic was eight seconds. Two of the ignition tests had to be halted after four minutes as the smoke being produced by the fire began to overwhelm the dedicated extraction system of the test facility (figure 3). 

Plastic Consumer Units in the UK have to be constructed in accordance with BS EN 60439 (replaced in 2011 by BS EN 61438). The plastic enclosures have to withstand 660°C glow wire product tests. The opinion of the author is that this test is not sufficient to ensure the safety of the occupiers in properties where plastic consumer units are installed. 
The data previously detailing fires that have originated within consumer units in the Glasgow area, resulting from various types of defective electrical connections, shows an increase in these life-threatening fires. 
The plastics used in the construction of consumer unit enclosures should therefore be more resistant to ignition from an internal defective electrical connection. In addition, the product should be constructed to ensure that any localised heating within the consumer unit should be contained within the product.




Tuesday, 23 December 2014

Wall mounted tv installation Glasgow

wes electrical 01418405236

Christmas 2014 has fast approached many of us this year and there is no better time to up grade an old tv set to a new energy efficient led number. with so many fantastic offers out the at the moment and possibly even better in the january sales you could pick yourself up a bargain and get it fitted on the wall for optimal visual experience, space saving and it just looks cooler on the wall than sitting on the stand.



we are an electrical installation company who over the years pioneered wall mounted tv installation from back in the day when sonos systems where wired and i had to deal with a mass amount of cables to supply and stream video and audio to individual rooms, now of course sonos systems are wireless and use wifi the connect to other devices.

As far as wall mounted tv installations go there are multiple options for what you can do with your installation as i tell all my customers you can get whatever you want done, the only issues are cost and how much disruption you are willing to take in you house until completion, apart from that the sky or the wall in the limit. (i have mounted on a ceiling but thats another matter) when we take on an installation for our customers, we mainly cover the west of scotland - (Glasgow renfrewshire ayrshire,) we do a site survey on what is possible, what you would like, and how much you are looking to spend on the installation products i.e hdmi quality / quantity, bracket type and finish.
once we have all the fundamentals arranges we pencil you in for a time and date and do the installation for you, it can usually take 2-3 hours to complete depending on what is getting installed.

we have 100% satisfaction for all our installations feel free to check out our website. wall mounted tv glasgow

westend glasgow electricians


Wednesday, 3 December 2014

TIPS FOR CCTV INSTALLATION

Tips on installing CCTV to your home. 


WES ELECTRICAL WESTEND GLASGOW


The prospect of drilling a hole through the outside wall of your house to run the power and video cable for a camera may seem a big job. With a little forethought it can be quite simple. 

Positioning of cameras
Most people want to hide the camera as much as possible. The modern cctv camera can easily be located under or on the fascia/soffit boards where the roof meets the wall. When located here it is sheltered from wind and rain and can be shaded from most sunlight. The height of the camera gives a good area of view and minimizes the risk of vandalism. 

Another advantage of this location is cabling. It is pretty easy to run the cables into the loft from this position. Many houses have a small ventilation gap between the roof tiles and the external wall, or a small hole may be drilled in the fascia board to gain access to the loft. 

Cabling
It is usually quite easy to pick up mains power in the loft or, if additional cabling is required it is now internal. Wireless transmission can be used for the video signal with the receiver being placed next to the monitor or recorder (TV, VCR, PC etc.). That's it, job done. 

A 'hard-wired' system is almost as easy to install. Locate the TV aerial down-lead that may be in the loft or run down the outside of the house, then run the CCTV camera video cable alongside the aerial cable, which will lead directly to the TV. 

A good method of connection is an RF modulator. This changes the camera's video output to an RF output. You can pipe the CCTV images down the existing TV aerial down-lead and view on the TV/VCR as if it were another channel. If your house is fitted with a TV distribution system, this method will allow the pictures to be seen on all the TV sets. 

Addition of Switchers etc.
Consider placing switchers, multiplexers or DVRs in the loft. This keeps all the cabling in the loft with just one output cable to your monitor. It also hides your recording device. 

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Friday, 28 November 2014

ELECTRICAL TESTING IN GLASGOW

WES ELECTRICAL WESTEND GLASGOW 01418405236

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Safe method of isolation.



The recommended procedure for proving dead and safe isolation should be by use of a test lamp or two pole voltage detector as recommended in HSE Guidance Note GS38 regulations.
Non-contact voltage indicators and multi-meters should not be used. The test instrument should be proved to be working on a known live source or proprietary proving unit before and after use. All phases of the supply and the neutral should be tested and proved dead before any work is commenced by a qualified electrician.




Test sequence and descriptions of test procedures.



The following tests are carried out with the main board / Consumers main switch isolated



1. Extenal earth fault loop impedance (ohms)


Reason: To establish that a good earth exists at the electrical installation in order for the remaining tests to go ahead.


Method: Disconnect the main earthing conductor from the main earthing terminal at the main distribution board. An earth fault loop impedance tester is connected at line and earth (main earthing conductor) at the supply side of the electrical installation and a test performed. Reconnect the main earthing conductor. The result is Ze and recorded on the test sheet. The prospective fault current is measured at the same time after the reconnection of the main earthing conductor at the main board.


2. Continuity of protective and equipotental bonding conductors


Reason: To check that all circuit protective conductors are continuous and are present at every electrical outlet / accessory on the circuit. Also to check that the main earthing conductor and main bonding conductors are continuous and correctly connected at the terminals.


Method 1: The line conductor is connected to the circuit protective conductor of the same circuit at the consumer unit and a measurement taken at ALL accesories on that circuit between line and c.p.c. The highest measurement obtained is recorded on the test report. 
Test result is R1 + R2. The line conductor and neutral conductor are then connected and the above repeated to obtain R1 + Rn


Method 2 (used for main earth and main bonding conductors): A wandering lead is connected to one end of the conductor to be tested and a measurement taken between the other end of this lead and the other end of the conductor. 
Test result is R2.
During this test polarity can be checked as well. The continuity of the neutral conductor can also be checked to determine R2.


3. Continuity of ring final circuit conductors


Reason: This test ensures that all ring final circuits are indeed a continuous ring with no interconnects or breaks within it.

Method: The line, neutral and earth conductors of the circuit are identified and a measurement from one end to the other end of each is taken. These results are r1, r2 and rn. 
The incoming line conductor is then connected to the outgoing earth conductor and the outgoing line conductor is connected to the incoming earth conductor. A measurement is then taken at ALL socket outlets on the ring. The highest of which is recorded on the report. 
This result is R1+R2 for that circuit. The above is then repeated using the neutral conductor instead of the earth conductor. This test provides R1+Rn which does not need to be recorded on the report but is essential to check the circuit correctly.


4. Insulation Resisitance testing


Reason: This test checks whether the insulation around a cable is still intact and has not broken down over time or has been separated from the rest of the ring. It is a good indicator of the age of an installation.

Method: An insulation resistance tester is connected across line and neutral tails at the origin of the supply. 500V are then pumped down the conductors to see if any voltage leaks across from one conductor to the other. The same is then done for the line and earth and the earth and neutral conductors.


5. Polarity checks


Reason: To check that all accesories are correctly connected to line, neutral and earth and that all switches and circuit breakers are connected in the line conductor only.

Method: The method for this is the same as for continuity and is usually done at the same time by operating switches etc whilst conducting the test.


6. Earth electrode resistance


Reason: To make sure that any earth electrode used is of a sufficiently low impedance to allow the timely operation of the RCD protecting the installation.

Method: An earth fault loop impedance tester is connected between line and earth at the origin of the supply and a test performed. The result of which is considered the resistance of the electrode (Ra).



The following tests are carried out with the Consumers main switch switch in the on position




7. Live polarity testing


Reason: To verify polarity of supply authorities system.


Method: An approved voltage indicator shall be used or test lamp to GS38. Using the approved voltage indicator, one probe shall be placed on the incoming neutral, and the other on the incoming line conductor, on the main breaker. The indicator should show it is live. One probe shall now be placed on the CPC and the other on the incoming line conductor. The indicator should show it is live. A test shall be preformed between CPC & incoming neutral. The indicator should show that it is not live.


8. Earth fault loop impedance


Reason: This test is done at the furthest point on a circuit in order to make sure the impedance of the earth path is not too high even at the furthest point so that sufficient current will flow under fault conditions to take out the circuit breaker protecting the circuit.

Method: An earth fault loop impedance tester is connected to line and earth at the furthest point on the circuit and the test performed.


9. RCD testing


Reason: To make sure RCD's trip within the correct time

Method: An RCD tester is connected and a test at 1/2 times, 1 times and 5 times the trip current is performed on each side of the cycle and a time of trip obtained. Usually milli-seconds with the highest being recorded. The manual test button is then pressed.


10. Functional testing

Reason: To make sure all switches, isolators, MCB's etc. work as they should.

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