The picture below shows an electrical manhole intended for underground installation being unloaded from the transport truck.
Picture 1 – The electrical manhole being unloaded
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=================
Most building works require at least one or two underground electrical manholes. That is because a building of significant size usually require a few hundred amperes of electric current at low voltage (i.e. 240 volt, 3 phase current).
Above a few hundred KVA (kilo-volt-amperes), the electricity supply authority usually delivers the electrical power to the consumer loads at higher than 240 volt, usually at 11,000 volts.
(Note: 100 amperes x 240 volt x 3 phases = 24,000 VA x 3 phases = 72,000 VA = 72 KVA. For readers who are intimidated by the KVA term, this is what KVA is. That is measure of electrical power delivered to a building. It is also the most common unit used in specifying the size and rating of electrical equipment and switchgears.)
Okay, back to the electrical manhole.
When the supply is at 11,000 volts (i.e. 11 KV), high voltage cables installed below ground level (i.e. underground) is the most popular method of electricity distribution unless the building is in remote areas such as the countryside.
So, in building works, we need at least one or two of these manholes to bring in the authority cables from outside the boundary of the building works to the electrical substation inside the building compound or the inside the building itself.
Picture 2 – The electrical manhole at a closer look
Notice the note I put in the picture saying “precast conduit sleeves”.
These sleeves were made in the factory to facilitate the connection of underground electrical conduits carrying the cables to the manhole.
If these openings on the concrete walls of the manhole are not made in the factory, then the openings have to be manually made at site using electric hammers etc.
Most of the times, some modifications are still needed because the high voltage cables are usually large and they are difficult to turn and bend.
The underground conduits may also not arrive at the manhole at the same levels of the precast sleeves. If they do, they may not all be at exactly 90-degree angles to the manhole walls.
This means some hacking still need to be done to the precast sleeves.
I forgot to tell you that the precast sleeves are made to accept 150 mm diameter of electrical conduits. It is a common practice to use 6 inch diameter underground conduits for electrical distribution cables.
Smaller sized conduits are also used, but they are generally for underground street lighting cables and compound lighting cables inside the building compound.
In these cases, 4 inch diameter conduits are used and they are installed when the compound lighting cables need to cross under internal roads.
I did not mean this post to be discussing underground cabling works. I just wanted to show some pictures of electrical underground manholes so that I can just refer to this post when talking about underground electrical manholes.
However, the above brief issues on the manhole are necessary to give some meaning to the pictures here.
So for the readers with more advanced knowledge on these things, please be patient with me. This blog is for beginners.
Picture 3 – An installed underground electrical manhole
This is how it looks after the manhole has been installed. Even though it is called “underground”, the manhole is not really totally “buried” below ground.
The exposed part of it is still visible and accessible at ground level.
Picture 4 – Manhole cover
This is the top of the electrical manhole, which is leveled to the finished ground level, exposed and accessible for access.
Observe carefully that there are 4 pieces of the manhole cover. These covers are made of reinforced concrete. So they are very heavy. Breaking it into 4 pieces make it easier to be opened by manually hand-lifting it.
Even at that smaller-sized, it usually takes at least 2 normal-sized persons to lift open a single piece after a few years. Yeah. I know. Hulk Hogan may only need two fingers to do it).
Picture 5 – The base of the manhole pit
You cannot just dig a hole of sufficient size in the ground and plant in the concrete electrical manhole.
If you do that, sooner or later one of the manholes would sink in deeper into the ground, or get tilted enough to break the underground electrical conduits and possibly damaging the underground cables.
When that happens, you would then need to carry out excavations when one of the cables need repairs or when additional cables need to be installed along the same underground route.
In fact this is the very reason the underground electrical conduits and manholes are used: to facilitate maintenance, repair and upgrading of the underground electric cables in future, long after the building is completed and occupied.
At the base of the opening in Picture 5 is a layer of sand. It is a practice to put some river sand at the base and compact it to give about 4 inch thick after compaction.
Of course, before that sand is poured in, the ground at the bottom should be firm and solid. If the soil at the bottom of the pit has been spoilt because of water accumulating there, then pit bottom must be excavated further to remove the spoilt earth. This also means more sand may be needed as the volume to be refilled would then be larger.
There is one very important I would like readers to note, especially those directly involved in construction.
You must NEVER allow the contractor to just install the manhole without first being inspected by someone responsible.
If the preparation of the base of the pit is not good enough, the manhole may sink in sooner than you would hope for. To repair it would require re-excavation works which are usually messy.
Someone may need to take the blame. It is not always easy to cover up mistakes like these.
Picture 6 – Excavated pit for an electrical manhole
I just include this picture to make my point above.
This particular opening in the ground was made in front of an electrical substation. It was supposed to be for the manhole of the same type and size as shown in the pictures above.
However, for some reasons the delivery of the factory-manufactured manhole did not arrive. So the opening was just left there. Sooner or later it would collect rainwater, which it did as can be seen in the picture.
Suppose one day the contractor calls you and say that he has finished installing the underground electrical manhole in front of the substation. With that the electrical authority can start pulling in the high voltage electrical cables.
In two weeks, the substation would be energized and the new building would have permanent electrical power that would also facilitate the testing and commissioning of all the electrical and mechanical services in the building, which has been delayed due to the delayed energization of the electrical substation.
This was a good news, and a reason for celebration. Of course, the real celebration should be AFTER the actual energization of the substation.
Being the one giving the good news to you, the contractor has made a dinner reservation at a nearby six-star hotel. It is a celebration and YOU are the man.
What would you do?
What would I do? I would accept the invitation to the dinner. After having a very nice meal and laughs, I would excuse myself earlier than normal. On the way out, I would tell the contractor to immediately start the arrangement to remove the installed manhole and prepare again the manhole pit in front of the substation.
Only after I say okay he would be allowed to re-install the manhole.
What would you do?
Copyright http://electricalinstallationwiringpicture.blogspot.com Underground electrical manhole
Electrical basics for beginners | Understanding electrical installations and wiring through pictures | The concepts behind electrical room design and substations
Wednesday, August 18, 2010
Thursday, July 29, 2010
Compound lighting foundation size
I am sending up the following three images on compound lighting pole foundation details to fulfill a request by a friend earlier today.
Image 1 – The overall diagram of a five-meter lighting pole
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================
He was supervising a construction job of several pumping stations at a remote location in the countryside.
The project was worth just above ten million (I think that was what he told me a few months ago), so the budget for the supervision team was not that high.
Being a little bit out of the way, not many engineers would be interested to fulfill the vacancies for the resident engineer posts with the salary the engineering consultant could afford to pay.
However, the construction works still have to proceed and the project still need to be completed and delivered on time. No main contractor would want to risk any possibility of delays especially in a design-and-build or a turnkey contract.
As usual, the best solution in this sort of situations is to employ just one resident engineer to supervise both the electrical parts of the work.
This way the salaries meant for two resident engineers (i.e. for electrical and mechanical resident engineers) is paid to just one making the vacant post much more attractive.
That was the kind of post this friend of mine took and he got a pretty good offer to supervise a relatively small jab.
Naturally there is a problem, however. He is a mechanical engineer who needs to look after all the electrical works also.
He needs a friend’s help now and then to ask for some free professional advice.
That was what happened today. He needed to advise the electrical contractor on the size of the foundation for the compound lighting pole.
Image 2 – The blow-up view of the foundation for the 5 meter compound light pole
There not much that I need to elaborate on this concrete foundation. It’s just a simple plinth with the size of 500mm x 500mm x 900mm.
Notice the mounting bolts and the high impact PVC pipe cast into the concrete.
This image above shows just one uPVC pipe sleeve. Normally you would want at least two sleeves: one to the left and one to the right because cables to the light poles are usually looped in and out from the previous pole and then to the next pole.
So the image above if for a pole that is on the end of the loop.
Observe also that the dimensions of the concrete base are sized at bit larger than the base plate or the bearing plate of the steel pole (See Image 3 below).
Image 3 – Bearing plate dimensions
This is to give enough clearance around all the mounting bolts so that there is enough strength of the concrete to withstand the load imposed to each of the bolt.
The size of the foundation above is actually one of the standard practices that I know for the light pole height shown above and you should have nothing to worry about.
Of course the type of the soil is a major factor. So if you have doubts just call the light pole supplier or just ask the civil engineer. This is just a simple common issue for them, so you should be able to get an immediate confirmation.
I have been using this size in all my projects and never had any problem.
See you again the next time.
Copyright http://electricalinstallationwiringpicture.blogspot.com Compound lighting foundation size
Image 1 – The overall diagram of a five-meter lighting pole
================ RELATED ARTICLES: Electric Cable Drum Pictures | Underground street light cables | Compound lighting storage yard | Feeder pillar single line diagram | Bollard light pictures | Feeder pillar hazard pictures | Compound Lighting Installation Pictures | Electrical installation pictures | Architectural Lighting
================
He was supervising a construction job of several pumping stations at a remote location in the countryside.
The project was worth just above ten million (I think that was what he told me a few months ago), so the budget for the supervision team was not that high.
Being a little bit out of the way, not many engineers would be interested to fulfill the vacancies for the resident engineer posts with the salary the engineering consultant could afford to pay.
However, the construction works still have to proceed and the project still need to be completed and delivered on time. No main contractor would want to risk any possibility of delays especially in a design-and-build or a turnkey contract.
As usual, the best solution in this sort of situations is to employ just one resident engineer to supervise both the electrical parts of the work.
This way the salaries meant for two resident engineers (i.e. for electrical and mechanical resident engineers) is paid to just one making the vacant post much more attractive.
That was the kind of post this friend of mine took and he got a pretty good offer to supervise a relatively small jab.
Naturally there is a problem, however. He is a mechanical engineer who needs to look after all the electrical works also.
He needs a friend’s help now and then to ask for some free professional advice.
That was what happened today. He needed to advise the electrical contractor on the size of the foundation for the compound lighting pole.
Image 2 – The blow-up view of the foundation for the 5 meter compound light pole
There not much that I need to elaborate on this concrete foundation. It’s just a simple plinth with the size of 500mm x 500mm x 900mm.
Notice the mounting bolts and the high impact PVC pipe cast into the concrete.
This image above shows just one uPVC pipe sleeve. Normally you would want at least two sleeves: one to the left and one to the right because cables to the light poles are usually looped in and out from the previous pole and then to the next pole.
So the image above if for a pole that is on the end of the loop.
Observe also that the dimensions of the concrete base are sized at bit larger than the base plate or the bearing plate of the steel pole (See Image 3 below).
Image 3 – Bearing plate dimensions
This is to give enough clearance around all the mounting bolts so that there is enough strength of the concrete to withstand the load imposed to each of the bolt.
The size of the foundation above is actually one of the standard practices that I know for the light pole height shown above and you should have nothing to worry about.
Of course the type of the soil is a major factor. So if you have doubts just call the light pole supplier or just ask the civil engineer. This is just a simple common issue for them, so you should be able to get an immediate confirmation.
I have been using this size in all my projects and never had any problem.
See you again the next time.
Copyright http://electricalinstallationwiringpicture.blogspot.com Compound lighting foundation size
Friday, July 23, 2010
Site fabricated electrical trunking
What will be the problem if an electrical contractor fabricates the electrical trunking at the construction site? Why do I make an issue of this matter?
Picture 1 – Electrical trunking already installed at a new building under construction
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===========
Majority of Clients and Consultants that I know specifically state that all electrical trunking and the related accessories should be factory-manufactured and should preferably be obtained from the same manufacturer.
This means that all parts and pieces that make up an electrical trunking installation should purchased as finished products from factory.
Observe from Picture 1 above that one of the electrical trunking has been bent. That was to make room for something else that would be installed there later (it was not yet installed at the time this picture was taken. I am not yet very sure myself what that something is… which reminds me that I need to check it out soon).
The point here is that now and then electrical trunking need to bend and turn around things and other services and equipment along their path inside a building.
Because of that, we need the angle pieces of the trunking.
However, fabricating an angle piece from a straight trunking piece is the most economical alternative for many electrical subcontractors. That is why many of them usually try very hard to use this alternative rather than buying them ready-made from factory as specifically required by the Contract Specifications.
I was once faced with a contractor who just bulldozed their way and installed the site-fabricated trunking bends for eleven of the twenty floors of an office building.
The contractor thought he could play hardball and force me to accept and approve the installation.
Too bad he lost the battle in the end and he had to spend all the manpower and the extra “factory-manufactured” materials to redo the trunking installation.
The worst thing was that all the wiring had already been installed.
The three pictures below show a trunking bend being fabricated by the electrical worker at a construction site that I was involved in.
I rejected these works also and the rectification work should be done by the electrical subcontractor. The contractor knew I would not accept this sort of quality, but he thought he was smart I guess.
Why such a big fuss over this matter?
Because the site fabricated trunking accessories are almost always of very poor quality. The finished product usually produces very sharp edges all over the piece.
The sharp edges cut into the insulation of the wiring cables during the cable installation. When the insulation is damaged all over the place along the length of a cable, then it is no longer a good cable no matter how much you paid for it.
Wiring cables that have been damaged in this way not only become a maintenance headache to the operation people after just a few years, they are also dangerous and can cause deadly electrical accidents.
I say it again: THEY ARE DANGEROUS AND DEADLY.
Picture 2 – 45-degree trunking bend
Picture 3 – Sharp edges of the trunking bend
Picture 4 – Site workbench where the trunking “accessories” are “manufactured”
That is all the time I have for this blog today. Visit this post, Electrical installation pictures, to see more pictures of electrical installations.
There are other posts that I have sent a few months back about electrical trunking installation. You need to browse around this blog see them. I will put their direct links to this post in a few days for the readers’ convenience.
One last note: I wish to apologize to my regular visitors for being away this past few weeks. I know this blog has been getting regular visits from quite a number of readers.
The last few projects that I have been involved in have been taking too much of my time and energy, too much more than I would normally like to spend.
I also wish to thank the readers who have left messages. If you like these pictures, visit again.
I, however, will not be answering messages yet on this blog because I think this blog has not yet enough contents.
Not only that, once I start answering your messages, then I would feel very guilty when I cannot spare time on them.
Again thank you for visiting. I sincerely hope that pictures and other information that I put up here are useful to you all.
See you again soon.
Copyright http://electricalinstallationwiringpicture.blogspot.com Site-fabricated electrical trunking
Picture 1 – Electrical trunking already installed at a new building under construction
========= RELATED ARTICLES: Underfloor trunking below structural rebars | MATV trunking riser | Conduit to trunking connections | Cable ladder pictures | Electrical conduits and trunking pictures | Electrical panel under water pipes | Electrical busduct installation pictures | Electric conduit installation pictures | Electric trunking installation pictures | Electric Panel Installation Pictures | FR electric cable installation pictures | Multi storey building electric closets | Underfloor trunking pictures | Electrical Services Color Codes | Light switch installation pictures | Electrical installation pictures
===========
Majority of Clients and Consultants that I know specifically state that all electrical trunking and the related accessories should be factory-manufactured and should preferably be obtained from the same manufacturer.
This means that all parts and pieces that make up an electrical trunking installation should purchased as finished products from factory.
Observe from Picture 1 above that one of the electrical trunking has been bent. That was to make room for something else that would be installed there later (it was not yet installed at the time this picture was taken. I am not yet very sure myself what that something is… which reminds me that I need to check it out soon).
The point here is that now and then electrical trunking need to bend and turn around things and other services and equipment along their path inside a building.
Because of that, we need the angle pieces of the trunking.
However, fabricating an angle piece from a straight trunking piece is the most economical alternative for many electrical subcontractors. That is why many of them usually try very hard to use this alternative rather than buying them ready-made from factory as specifically required by the Contract Specifications.
I was once faced with a contractor who just bulldozed their way and installed the site-fabricated trunking bends for eleven of the twenty floors of an office building.
The contractor thought he could play hardball and force me to accept and approve the installation.
Too bad he lost the battle in the end and he had to spend all the manpower and the extra “factory-manufactured” materials to redo the trunking installation.
The worst thing was that all the wiring had already been installed.
The three pictures below show a trunking bend being fabricated by the electrical worker at a construction site that I was involved in.
I rejected these works also and the rectification work should be done by the electrical subcontractor. The contractor knew I would not accept this sort of quality, but he thought he was smart I guess.
Why such a big fuss over this matter?
Because the site fabricated trunking accessories are almost always of very poor quality. The finished product usually produces very sharp edges all over the piece.
The sharp edges cut into the insulation of the wiring cables during the cable installation. When the insulation is damaged all over the place along the length of a cable, then it is no longer a good cable no matter how much you paid for it.
Wiring cables that have been damaged in this way not only become a maintenance headache to the operation people after just a few years, they are also dangerous and can cause deadly electrical accidents.
I say it again: THEY ARE DANGEROUS AND DEADLY.
Picture 2 – 45-degree trunking bend
Picture 3 – Sharp edges of the trunking bend
Picture 4 – Site workbench where the trunking “accessories” are “manufactured”
That is all the time I have for this blog today. Visit this post, Electrical installation pictures, to see more pictures of electrical installations.
There are other posts that I have sent a few months back about electrical trunking installation. You need to browse around this blog see them. I will put their direct links to this post in a few days for the readers’ convenience.
One last note: I wish to apologize to my regular visitors for being away this past few weeks. I know this blog has been getting regular visits from quite a number of readers.
The last few projects that I have been involved in have been taking too much of my time and energy, too much more than I would normally like to spend.
I also wish to thank the readers who have left messages. If you like these pictures, visit again.
I, however, will not be answering messages yet on this blog because I think this blog has not yet enough contents.
Not only that, once I start answering your messages, then I would feel very guilty when I cannot spare time on them.
Again thank you for visiting. I sincerely hope that pictures and other information that I put up here are useful to you all.
See you again soon.
Copyright http://electricalinstallationwiringpicture.blogspot.com Site-fabricated electrical trunking
Thursday, May 27, 2010
Temporary electrical cabling
Today readers get to see a few pictures of bad practices in the utilization of temporary electrical supply at a building construction site.
Picture 1 – Temporary electrical panel
===== RELATED ARTICLES: Temporary electrical installation pictures | Temporary electrical installation pictures | Temporary Electrical Earthing Pictures | Temporary electrical panel and cords pictures |
===========
I got involved with this new building project since a few weeks ago.
After reporting to work at the construction site, I spent the first few days attending a few meetings and on the fourth day I took my first round of general inspection around the building under construction.
I went out alone on that first inspection, bringing with me my old and cheap Canon digital camera. It was really a cheap camera and that is probably the reason the picture quality here are not so good.
My previous digital camera was much better but it got stolen when my car was broken into.
First things first
The first thing that I look for when starting on a new project site is always the temporary electricity supply equipment and their associated temporary cabling and wiring works.
There can be hundreds of workers are involved during peak period of activities in a building job of a few million dollars.
With a bad temporary supply installation and with most workers being generally ignorant of the dangers of temporary electricity, the risk of fatal electrical accidents is always high.
I did my round and took a few pictures of temporary electrical panels being used, the temporary supply cabling, wiring, and extension cords that were taking supply from temporary panels.
I selected a few of the picture shots that I took and sent it to the Main Contractor’s Project Manager together with the following Site Memo.
You can see a few of the pictures of the temporary electricity supply DB and their cabling works toward the end of this post.
SITE MEMO:
Dear Sir,
Re: Temporary electricity supply: Electric shock hazards
As I have explained on Saturday last week, please find attached photographs of the temporary electrical cabling.
I believe the photos are self-explanatory. However, I wish to highlight the following points:
Many extension cords do not have the grounding cable.
The extension cords are laid on the floor along main work traffic. Cables can be damaged leading to exposures of LIVE cables. A few have already been damaged and improperly patched up.
Observe that the area is a very wet area. The risks of electrocution here is very high.
I suggest the following action be taken IMMEDIATELY:
If possible, the temporary DB is relocated to a more suitable and DRY area.
Enforce the rules that all subcontractors run their extension cords at high level along walls or columns.
Enforce the rules that all extension cords have a working grounding conductor.
It is my opinion that the present situation is VERY DANGEROUS and a fatal electric shock accident can happen any time.
Regards,
Lee Wan Seng
Resident Electrical Engineer
Picture 2 – Temporary electrical cabinet
Picture 2 above shows the overall view of the temporary electrical cabinet where the temporary electric panel is located.
I know that many electrical readers are surprised by the way I accept these equipments and installations.
The temporary panel in the pictures is not what I would use if I am in charge.
Here I was not in charge. I was the resident engineer representing the professional electrical consultant in a design-and-build contract.
In this type of contract, the main contractor is the boss and the paymaster.
And this project was in a “third world country".
We in the construction and engineering consultant industry cannot turn the standard of our construction practices overnight, especially not in the design-and-build or turnkey types of contracts.
What we can do is to set out priorities in an order that can still be implemented on the ground within a particular contract scenario.
In this case, it was an issue of safety of human lives.
Even in this matter of life and death of many human lives, priorities must be set properly so that it can be implemented.
I could have rejected the whole temporary electrical DB and the temporary cabling in the picture.
In many situations, I have done so.
However, in real life situations, political factors are always present and everywhere, especially where there is a lot of money involved. That is the nature of life that I know.
To say it simply, if I rejected the makeshift temporary electrical DB, I would have been kicked out of the project in a matter of a few weeks and the main contractor would have easily found a replacement that would bend to their wills.
Of course I could easily find myself another job, even with much better paychecks and benefits if I want to.
However, nothing good would come out as far as the electrical safety at this construction site is concerned. It may even get worse.
That is why I sent out the above Site Memo.
If the Main Contractor take action as I advised (which they did immediately after receiving the memo) in the above Site Memo, then I would have made a strong improvement. That was a good first step.
The point here is that handling construction issues on the ground has as much to do with diplomacy and PR works as with technical issues.
One has to properly balance a number of top priority matters in order to get things improved enough.
That is a measure of effectiveness of the site supervision team in the real construction world.
Going back to the reason I made this blog, its objective is mainly to share pictures. With this method, I share my experience with the readers. Good experience, and the bad ones.
You will find lots of pictures showing good electrical installations here. You will also find tons of bad installations. I am not recommending anything by showing all these pictures, unless I specifically say so.
As long as readers find some uses from the pictures, then I would have accomplished my purpose by sharing the pictures that I have in this blog.
Enough said. Now let’s get back to the pictures.
Picture 3 – A view of the wet area around the electrical panel
This picture shows one situation was with a wet area around the temporary panel and unsuitable extension cords laying around on the building's ground floor.
From the point of view of safety practices and regulations, I think this real life example has broken about all the relevant codes in the book.
Picture 4 – Damaged extension cord
This shows a closer view of the extension cords laying on the work floor. They have no armor and could be easily be damaged.
A few have been already damaged and improperly patched up.
Picture 5 – Closer view of the repaired extension cables
Picture 6 – One of the portable electric tools
Picture 7 – Extension cords on the floor
Picture 8 – An example of electrical plug without earthing connection
I wish to emphasize a little bit here.
Why do you think the workers did not connect the green earth cable to the plug?
The extension cord already has 3 cables one of which was meant for grounding.
So why such a reluctance to do it?
The reason is almost the same most of the time. The ELCB on the electrical panel may trip if the green earthing cable is connected.
Portable electrical tools used at construction sites are mostly motorized tools (e.g. Drills, grinders, electric hammers, etc).
These tools always have an electric motor underneath the casing.
An electric motor always has a coil that transforms the electrical energy into the mechanical energy that do the work.
That is where the problem comes from.
Motor coils have a tendency to leak electrical voltage. Other moving parts behave similarly also.
The leaked electric voltage (Note: an electric voltage is an electrical pressure much like a water pressure inside a water pipe) would turn into a leakage current if the electric tool is properly earthed or grounded.
The flow of the leakage current would be detected by the ELCB (earth leakage circuit breaker) unit on the electrical panel and the ELCB would trip.
If the grounding conductor is not connected as shown in Picture 8, then the ELCB would not trip. So the worker using the portable electric tool could keep on working.
In another word, frequent trippings of the ELCB is a nuisance to the workers.
That is why they disconnect the green grounding conductor of the extension cord.
But then, without the grounding cable, the worker has zero protection against the risk of electric shock.
By that, I really mean absolutely NO PROTECTION AT ALL AGAINST ELECTRIC SHOCKS.
Picture 9 – Grounding of the temporary supply through the steel wire armor of the multi-core armored distribution cable
That is all I have for today. See you again in the next post.
Copyright http://electricalinstallationwiringpicture.blogspot.com Temporary electrical cabling
Picture 1 – Temporary electrical panel
===== RELATED ARTICLES: Temporary electrical installation pictures | Temporary electrical installation pictures | Temporary Electrical Earthing Pictures | Temporary electrical panel and cords pictures |
===========
I got involved with this new building project since a few weeks ago.
After reporting to work at the construction site, I spent the first few days attending a few meetings and on the fourth day I took my first round of general inspection around the building under construction.
I went out alone on that first inspection, bringing with me my old and cheap Canon digital camera. It was really a cheap camera and that is probably the reason the picture quality here are not so good.
My previous digital camera was much better but it got stolen when my car was broken into.
First things first
The first thing that I look for when starting on a new project site is always the temporary electricity supply equipment and their associated temporary cabling and wiring works.
There can be hundreds of workers are involved during peak period of activities in a building job of a few million dollars.
With a bad temporary supply installation and with most workers being generally ignorant of the dangers of temporary electricity, the risk of fatal electrical accidents is always high.
I did my round and took a few pictures of temporary electrical panels being used, the temporary supply cabling, wiring, and extension cords that were taking supply from temporary panels.
I selected a few of the picture shots that I took and sent it to the Main Contractor’s Project Manager together with the following Site Memo.
You can see a few of the pictures of the temporary electricity supply DB and their cabling works toward the end of this post.
SITE MEMO:
Dear Sir,
Re: Temporary electricity supply: Electric shock hazards
As I have explained on Saturday last week, please find attached photographs of the temporary electrical cabling.
I believe the photos are self-explanatory. However, I wish to highlight the following points:
Many extension cords do not have the grounding cable.
The extension cords are laid on the floor along main work traffic. Cables can be damaged leading to exposures of LIVE cables. A few have already been damaged and improperly patched up.
Observe that the area is a very wet area. The risks of electrocution here is very high.
I suggest the following action be taken IMMEDIATELY:
If possible, the temporary DB is relocated to a more suitable and DRY area.
Enforce the rules that all subcontractors run their extension cords at high level along walls or columns.
Enforce the rules that all extension cords have a working grounding conductor.
It is my opinion that the present situation is VERY DANGEROUS and a fatal electric shock accident can happen any time.
Regards,
Lee Wan Seng
Resident Electrical Engineer
Picture 2 – Temporary electrical cabinet
Picture 2 above shows the overall view of the temporary electrical cabinet where the temporary electric panel is located.
I know that many electrical readers are surprised by the way I accept these equipments and installations.
The temporary panel in the pictures is not what I would use if I am in charge.
Here I was not in charge. I was the resident engineer representing the professional electrical consultant in a design-and-build contract.
In this type of contract, the main contractor is the boss and the paymaster.
And this project was in a “third world country".
We in the construction and engineering consultant industry cannot turn the standard of our construction practices overnight, especially not in the design-and-build or turnkey types of contracts.
What we can do is to set out priorities in an order that can still be implemented on the ground within a particular contract scenario.
In this case, it was an issue of safety of human lives.
Even in this matter of life and death of many human lives, priorities must be set properly so that it can be implemented.
I could have rejected the whole temporary electrical DB and the temporary cabling in the picture.
In many situations, I have done so.
However, in real life situations, political factors are always present and everywhere, especially where there is a lot of money involved. That is the nature of life that I know.
To say it simply, if I rejected the makeshift temporary electrical DB, I would have been kicked out of the project in a matter of a few weeks and the main contractor would have easily found a replacement that would bend to their wills.
Of course I could easily find myself another job, even with much better paychecks and benefits if I want to.
However, nothing good would come out as far as the electrical safety at this construction site is concerned. It may even get worse.
That is why I sent out the above Site Memo.
If the Main Contractor take action as I advised (which they did immediately after receiving the memo) in the above Site Memo, then I would have made a strong improvement. That was a good first step.
The point here is that handling construction issues on the ground has as much to do with diplomacy and PR works as with technical issues.
One has to properly balance a number of top priority matters in order to get things improved enough.
That is a measure of effectiveness of the site supervision team in the real construction world.
Going back to the reason I made this blog, its objective is mainly to share pictures. With this method, I share my experience with the readers. Good experience, and the bad ones.
You will find lots of pictures showing good electrical installations here. You will also find tons of bad installations. I am not recommending anything by showing all these pictures, unless I specifically say so.
As long as readers find some uses from the pictures, then I would have accomplished my purpose by sharing the pictures that I have in this blog.
Enough said. Now let’s get back to the pictures.
Picture 3 – A view of the wet area around the electrical panel
This picture shows one situation was with a wet area around the temporary panel and unsuitable extension cords laying around on the building's ground floor.
From the point of view of safety practices and regulations, I think this real life example has broken about all the relevant codes in the book.
Picture 4 – Damaged extension cord
This shows a closer view of the extension cords laying on the work floor. They have no armor and could be easily be damaged.
A few have been already damaged and improperly patched up.
Picture 5 – Closer view of the repaired extension cables
Picture 6 – One of the portable electric tools
Picture 7 – Extension cords on the floor
Picture 8 – An example of electrical plug without earthing connection
I wish to emphasize a little bit here.
Why do you think the workers did not connect the green earth cable to the plug?
The extension cord already has 3 cables one of which was meant for grounding.
So why such a reluctance to do it?
The reason is almost the same most of the time. The ELCB on the electrical panel may trip if the green earthing cable is connected.
Portable electrical tools used at construction sites are mostly motorized tools (e.g. Drills, grinders, electric hammers, etc).
These tools always have an electric motor underneath the casing.
An electric motor always has a coil that transforms the electrical energy into the mechanical energy that do the work.
That is where the problem comes from.
Motor coils have a tendency to leak electrical voltage. Other moving parts behave similarly also.
The leaked electric voltage (Note: an electric voltage is an electrical pressure much like a water pressure inside a water pipe) would turn into a leakage current if the electric tool is properly earthed or grounded.
The flow of the leakage current would be detected by the ELCB (earth leakage circuit breaker) unit on the electrical panel and the ELCB would trip.
If the grounding conductor is not connected as shown in Picture 8, then the ELCB would not trip. So the worker using the portable electric tool could keep on working.
In another word, frequent trippings of the ELCB is a nuisance to the workers.
That is why they disconnect the green grounding conductor of the extension cord.
But then, without the grounding cable, the worker has zero protection against the risk of electric shock.
By that, I really mean absolutely NO PROTECTION AT ALL AGAINST ELECTRIC SHOCKS.
Picture 9 – Grounding of the temporary supply through the steel wire armor of the multi-core armored distribution cable
That is all I have for today. See you again in the next post.
Copyright http://electricalinstallationwiringpicture.blogspot.com Temporary electrical cabling
Tuesday, May 18, 2010
Underfloor trunking pictures
The underfloor trunking system has been around for a long time. The first time I saw it was inside an application guide published by a public telecommunication company.
The technical manual was already very old and I was in the first year of real professional work after my graduation. That was 23 years ago.
Picture 1 – Underfloor service box installation in progress
===== RELATED ARTICLES: Underfloor trunking below structural rebars | MATV trunking riser | Conduit to trunking connections | Cable ladder pictures | Electrical conduits and trunking pictures | Electrical panel under water pipes | Electrical busduct installation pictures | Electric conduit installation pictures | Electric trunking installation pictures | Electric Panel Installation Pictures | FR electric cable installation pictures | Multi storey building electric closets | Site-fabricated electrical trunking | Electrical Services Color Codes | Light switch installation pictures | Electrical installation pictures
===========
Why do we need an underfloor trunking system?
An underfloor trunking system is an alternative way of providing the dedicated routes to run electrical cables, telephone cables or any other wiring cables you can think of.
I said wiring cables. An 11KV cable is not a wiring cable. A 25 sq.mm electrical feeder cable to supply an 11 KW fire pump panel is not a wiring cable.
(Note: 25 sq.mm means 25 millimeter square. It is a measure of the net cross-sectional area of the electrical conductors of an electric cable).
The 1.5 sq.mm cables that are used for wiring the office lights are categorized wiring cables.
The 2.5 sq.mm or 4 sq.mm cables used in socket outlet wiring are also categorized as wiring cables.
That is on the electric power cables.
On the telephone side, the telephone wiring cables going to each telephone outlet in an office area are also called wiring cables.
But an incoming 100-pair telephone cable from the public telephone company into a multi-storey office building is not a wiring cable.
Likewise, a Cat 5 computer network cables going to the office computers from the server rooms can be called wiring cables.
However, a multi-core fiber optic cables connecting two computer buildings cannot be called wiring cables.
So those cables categorized as wiring cables can be run inside the underfloor trunking system.
In fact, the underfloor trunking has been invented specifically for this purpose.
Why the special treatment is given to the underfloor trunking?
Why not use the normal conduit and trunking? (See the conduit and trunking pictures here: Conduit installation pictures; Electric trunking pictures.)
The underfloor trunking system was developed long before I started my career in electrical engineering.
However, I think I can guess why there was a need for this system.
The need arose because of the popularity of open office layout system in the design of buildings.
There is no doubt that many residential buildings also use underfloor trunking systems. However, these buildings do not really have to use this system. The normal conduit and trunking system would serve the purpose perfectly well.
However, in an open office system, it is difficult to bring the wiring cables to the working tables in the middle of an office space (i.e. away from the walls) without running the cables inside the floor.
With many tables away from the walls, then many trunking and conduit need to be cast into the concrete floor.
Furthermore, different types of cables (eg. electrical and computer network cables) need to be run in different trunking and conduits totally segregated from each other.
In the end there were many trunking and conduit running all over the place inside the concrete floor slab of an office building with the open office concept of design.
So gradually the underfloor trunking concept developed, naturally.
Picture 2 – The underfloor trunking installation in progress
This picture shows a stretch of underfloor trunking installation in progress.
Notice that the floor reinforced concrete slab has been cast. The underfloor trunking was laid onto the already completed structural slab of the floor.
After the underfloor trunking components that need to be cast in have been laid out and fixed, a layer of concrete (called screeding) is poured to the floor to a thickness of about 50mm.
This additional two inch of concrete would cover the trunking parts, but the junction box would be exposed for access.
The thickness of the concrete screeding should be enough to give strength (and therefore would not crack) at the thinnest areas, which are the areas above the trunking parts.
Observe the notes that I gave in the picture.
During installation, there is always some time lapse between the installation pf the underfloor trunking parts and the pouring of the screeding concrete.
During this time, the trunking, junction boxes and service boxes need to be firmly held in place temporarily.
Steel bands and lean concrete are used for this purpose.
The temporary cover for the junction box opening is installed to prevent the fluid concrete from flowing into it during the concreting work. This temporary cover is made of soft metals and is usually supplied together with the junction box or the service box unit.
Notice also that there are three lengths of trunking installed together. So it is a 3-compartment trunking system. It could have been a 4-compartment or 2-compartment.
Here the trunking material is made of high-impact PVC trunking. However, an underfloor trunking can also be made of metals.
What is the difference between a service box and a junction box?
I should have explained this earlier so that beginners do not get confused.
A service box is a box along the underfloor trunking where the user can connect to the power outlet, telephone socket and computer socket.
It is the point of “service”.
Picture 3 below shows how a service box looks like.
Picture 3 – An underfloor service box
While a junction box is provided to facilitate the drawing in of cables during installation and maintenance.
It is also provided where a trunking need to make a bend and where it branches off.
That is why it is called a “junction” box.
Picture 4 – A completed underfloor junction box
Observe that the completed junction box cover is firmly fixed with 4 mounting screws at the corners.
On the other hand, the cover of the service box is designed so it can easily be open frequently.
That is because the service box is designed for user access. This is where users plug in their appliances just like the wall sockets.
Picture 5 – Vertical access box
The underfloor trunking resides at the floor. However, the cabling inside the trunking must come from the distribution panels somewhere.
If the distribution panel is located at the wall, then there must be a connection between the trunking inside the concrete floor and those at the walls.
That is the purpose of the vertical access box in Picture 5 above.
Sometimes, the electrical distribution panel is located inside the electrical riser which is some distance away. Usually the most convenient method of running the main trunking by hanger brackets above the ceiling.
Then at convenient locations, a set of droppers are installed to connect to the underfloor trunking. This is shown in Picture 6 below.
Picture 6 – Vertical access connection to trunking above ceiling
Picture 7 below shows another view of a junction box and underfloor trunking installation is progress, before the floor concrete screeding was poured in.
Picture 7 – Junction box and underfloor trunking picture
Construction works are never free from errors. Picture 8 below shows that a finished floor had to be hacked in order to extend the wiring from a junction box to the dry wall.
Picture 8 – Wall socket wired from an underfloor junction box
This was actually a last minute decision that was made to add another general purpose electrical outlet to the wall.
Theoretically it is best to wire general purpose electrical sockets on walls from separate circuits (better still, from a separate section of the busbar inside the electrical DB) than those inside the underfloor trunking, which supplies the work computers and other high priority equipment.
This is because the general purpose sockets are those used for such things as electric kettle, vacuum cleaners and other similar appliances.
Defects and faults in these appliances can cause trippings of the earth leakage circuit breaker (ELCB) at the electrical distribution panel, which can cause annoyances and other more genuine problems. (See pictures of ELCB at this post, 1-phase ELCB connection pictures.)
Update (March 15, 2014):
I have in my collections a lot pictures of materials that have been delivered to construction sites for installation of electrical systems.
For a long time this matter has been tickling my thoughts when I search through the pictures to attach to my posts.
Such a waste. These pictures has been helping me a lot of my work. Surely it must be of value to many people out there who still have no chance yet to get involved in actual electrical installation works.
Of course I can just upload all these pictures into the internet. But I don't think Google's search engine is smart enough to understand pictures and choose the right one for web users who are looking for them. There are probably trillions and trillions of pictures on the internet.
I cannot really make much of an article from pictures of electrical materials still in the plastic packings. It is too difficult. It seems too trivial, and I am not a much of a writer in the first place.
Today it just clicked in my head that I do not really need to write articles for these type of pictures. I can just attach the related one at the end of a related post. That's it!
I only need to write a few words to accompany each picture. The original post already says enough.
So with this revelation I am going to expand all of my posts to include a new section called "MORE RELATED PICTURES".
There I will gradually attach related pictures with a short description for each picture. I somehow a story clicks in my brain, then you will see a short story about the materials in the picture also.
If not, then just the description of the materials.
xxx MORE RELATED PICTURES xxx
Picture 09 - uPVC duct materials for an underfloor trunking system installation
This is the first picture that I will attach to this post today.
If you observe carefully, the trunking material are still on back of the delivery truck.
These are 3 inch by 1 inch uPVC ducts if I am not mistaken. The picture was from one of my office building projects.
If you enlarge the picture, you may notice that there are water droplets on the materials.
Well, this is another aspects of electrical construction which is proper handling of materials and equipment during loading and unloading, delivery and storage.
In this case here, the delivery truck people did not seem to care enough to put the rain cover over the material.
This happen to be not an issue here because the uPVC material have not problem with rainwater such as this.
However, it was still not a proper way to delivery the materials to a client who pay good money for them.
One thing that I wish to say on this picture is that we should always witness the delivery, and unloading of materials to a project site.
There are many types of materials and equipment that can get damaged or deteriorate in quality considerable when not handles properly during delivery, loading / unloading, and storage.
If the damages are noticeable during inspection, then you only need to reject the materials or equipment. Then they can be returned back to the manufacturer or his supplier.
What if you did not notice anything and proceed with the certification for payment and later found out that the materials have been damaged?
They may be a difficult dispute over who caused the damages. I have been through this many times.
A manufacturer might say the materials have been damaged during the storage at the client's store.
Anyway, that is all I wish to say on this. I will upload other pictures the the underfloor trunking installation soon.
Copyright http://electricalinstallationwiringpicture.blogspot.com Underfloor trunking pictures
The technical manual was already very old and I was in the first year of real professional work after my graduation. That was 23 years ago.
Picture 1 – Underfloor service box installation in progress
===== RELATED ARTICLES: Underfloor trunking below structural rebars | MATV trunking riser | Conduit to trunking connections | Cable ladder pictures | Electrical conduits and trunking pictures | Electrical panel under water pipes | Electrical busduct installation pictures | Electric conduit installation pictures | Electric trunking installation pictures | Electric Panel Installation Pictures | FR electric cable installation pictures | Multi storey building electric closets | Site-fabricated electrical trunking | Electrical Services Color Codes | Light switch installation pictures | Electrical installation pictures
===========
Why do we need an underfloor trunking system?
An underfloor trunking system is an alternative way of providing the dedicated routes to run electrical cables, telephone cables or any other wiring cables you can think of.
I said wiring cables. An 11KV cable is not a wiring cable. A 25 sq.mm electrical feeder cable to supply an 11 KW fire pump panel is not a wiring cable.
(Note: 25 sq.mm means 25 millimeter square. It is a measure of the net cross-sectional area of the electrical conductors of an electric cable).
The 1.5 sq.mm cables that are used for wiring the office lights are categorized wiring cables.
The 2.5 sq.mm or 4 sq.mm cables used in socket outlet wiring are also categorized as wiring cables.
That is on the electric power cables.
On the telephone side, the telephone wiring cables going to each telephone outlet in an office area are also called wiring cables.
But an incoming 100-pair telephone cable from the public telephone company into a multi-storey office building is not a wiring cable.
Likewise, a Cat 5 computer network cables going to the office computers from the server rooms can be called wiring cables.
However, a multi-core fiber optic cables connecting two computer buildings cannot be called wiring cables.
So those cables categorized as wiring cables can be run inside the underfloor trunking system.
In fact, the underfloor trunking has been invented specifically for this purpose.
Why the special treatment is given to the underfloor trunking?
Why not use the normal conduit and trunking? (See the conduit and trunking pictures here: Conduit installation pictures; Electric trunking pictures.)
The underfloor trunking system was developed long before I started my career in electrical engineering.
However, I think I can guess why there was a need for this system.
The need arose because of the popularity of open office layout system in the design of buildings.
There is no doubt that many residential buildings also use underfloor trunking systems. However, these buildings do not really have to use this system. The normal conduit and trunking system would serve the purpose perfectly well.
However, in an open office system, it is difficult to bring the wiring cables to the working tables in the middle of an office space (i.e. away from the walls) without running the cables inside the floor.
With many tables away from the walls, then many trunking and conduit need to be cast into the concrete floor.
Furthermore, different types of cables (eg. electrical and computer network cables) need to be run in different trunking and conduits totally segregated from each other.
In the end there were many trunking and conduit running all over the place inside the concrete floor slab of an office building with the open office concept of design.
So gradually the underfloor trunking concept developed, naturally.
Picture 2 – The underfloor trunking installation in progress
This picture shows a stretch of underfloor trunking installation in progress.
Notice that the floor reinforced concrete slab has been cast. The underfloor trunking was laid onto the already completed structural slab of the floor.
After the underfloor trunking components that need to be cast in have been laid out and fixed, a layer of concrete (called screeding) is poured to the floor to a thickness of about 50mm.
This additional two inch of concrete would cover the trunking parts, but the junction box would be exposed for access.
The thickness of the concrete screeding should be enough to give strength (and therefore would not crack) at the thinnest areas, which are the areas above the trunking parts.
Observe the notes that I gave in the picture.
During installation, there is always some time lapse between the installation pf the underfloor trunking parts and the pouring of the screeding concrete.
During this time, the trunking, junction boxes and service boxes need to be firmly held in place temporarily.
Steel bands and lean concrete are used for this purpose.
The temporary cover for the junction box opening is installed to prevent the fluid concrete from flowing into it during the concreting work. This temporary cover is made of soft metals and is usually supplied together with the junction box or the service box unit.
Notice also that there are three lengths of trunking installed together. So it is a 3-compartment trunking system. It could have been a 4-compartment or 2-compartment.
Here the trunking material is made of high-impact PVC trunking. However, an underfloor trunking can also be made of metals.
What is the difference between a service box and a junction box?
I should have explained this earlier so that beginners do not get confused.
A service box is a box along the underfloor trunking where the user can connect to the power outlet, telephone socket and computer socket.
It is the point of “service”.
Picture 3 below shows how a service box looks like.
Picture 3 – An underfloor service box
While a junction box is provided to facilitate the drawing in of cables during installation and maintenance.
It is also provided where a trunking need to make a bend and where it branches off.
That is why it is called a “junction” box.
Picture 4 – A completed underfloor junction box
Observe that the completed junction box cover is firmly fixed with 4 mounting screws at the corners.
On the other hand, the cover of the service box is designed so it can easily be open frequently.
That is because the service box is designed for user access. This is where users plug in their appliances just like the wall sockets.
Picture 5 – Vertical access box
The underfloor trunking resides at the floor. However, the cabling inside the trunking must come from the distribution panels somewhere.
If the distribution panel is located at the wall, then there must be a connection between the trunking inside the concrete floor and those at the walls.
That is the purpose of the vertical access box in Picture 5 above.
Sometimes, the electrical distribution panel is located inside the electrical riser which is some distance away. Usually the most convenient method of running the main trunking by hanger brackets above the ceiling.
Then at convenient locations, a set of droppers are installed to connect to the underfloor trunking. This is shown in Picture 6 below.
Picture 6 – Vertical access connection to trunking above ceiling
Picture 7 below shows another view of a junction box and underfloor trunking installation is progress, before the floor concrete screeding was poured in.
Picture 7 – Junction box and underfloor trunking picture
Construction works are never free from errors. Picture 8 below shows that a finished floor had to be hacked in order to extend the wiring from a junction box to the dry wall.
Picture 8 – Wall socket wired from an underfloor junction box
This was actually a last minute decision that was made to add another general purpose electrical outlet to the wall.
Theoretically it is best to wire general purpose electrical sockets on walls from separate circuits (better still, from a separate section of the busbar inside the electrical DB) than those inside the underfloor trunking, which supplies the work computers and other high priority equipment.
This is because the general purpose sockets are those used for such things as electric kettle, vacuum cleaners and other similar appliances.
Defects and faults in these appliances can cause trippings of the earth leakage circuit breaker (ELCB) at the electrical distribution panel, which can cause annoyances and other more genuine problems. (See pictures of ELCB at this post, 1-phase ELCB connection pictures.)
Update (March 15, 2014):
I have in my collections a lot pictures of materials that have been delivered to construction sites for installation of electrical systems.
For a long time this matter has been tickling my thoughts when I search through the pictures to attach to my posts.
Such a waste. These pictures has been helping me a lot of my work. Surely it must be of value to many people out there who still have no chance yet to get involved in actual electrical installation works.
Of course I can just upload all these pictures into the internet. But I don't think Google's search engine is smart enough to understand pictures and choose the right one for web users who are looking for them. There are probably trillions and trillions of pictures on the internet.
I cannot really make much of an article from pictures of electrical materials still in the plastic packings. It is too difficult. It seems too trivial, and I am not a much of a writer in the first place.
Today it just clicked in my head that I do not really need to write articles for these type of pictures. I can just attach the related one at the end of a related post. That's it!
I only need to write a few words to accompany each picture. The original post already says enough.
So with this revelation I am going to expand all of my posts to include a new section called "MORE RELATED PICTURES".
There I will gradually attach related pictures with a short description for each picture. I somehow a story clicks in my brain, then you will see a short story about the materials in the picture also.
If not, then just the description of the materials.
xxx MORE RELATED PICTURES xxx
Picture 09 - uPVC duct materials for an underfloor trunking system installation
This is the first picture that I will attach to this post today.
If you observe carefully, the trunking material are still on back of the delivery truck.
These are 3 inch by 1 inch uPVC ducts if I am not mistaken. The picture was from one of my office building projects.
If you enlarge the picture, you may notice that there are water droplets on the materials.
Well, this is another aspects of electrical construction which is proper handling of materials and equipment during loading and unloading, delivery and storage.
In this case here, the delivery truck people did not seem to care enough to put the rain cover over the material.
This happen to be not an issue here because the uPVC material have not problem with rainwater such as this.
However, it was still not a proper way to delivery the materials to a client who pay good money for them.
One thing that I wish to say on this picture is that we should always witness the delivery, and unloading of materials to a project site.
There are many types of materials and equipment that can get damaged or deteriorate in quality considerable when not handles properly during delivery, loading / unloading, and storage.
If the damages are noticeable during inspection, then you only need to reject the materials or equipment. Then they can be returned back to the manufacturer or his supplier.
What if you did not notice anything and proceed with the certification for payment and later found out that the materials have been damaged?
They may be a difficult dispute over who caused the damages. I have been through this many times.
A manufacturer might say the materials have been damaged during the storage at the client's store.
Anyway, that is all I wish to say on this. I will upload other pictures the the underfloor trunking installation soon.
Copyright http://electricalinstallationwiringpicture.blogspot.com Underfloor trunking pictures
Monday, May 17, 2010
A simple electrical installation
Anybody looking for a layout and schematic diagram of a simple electrical installation?
Diagram 1 – Simple house electrical layout
=================
RELATED ARTICLES: Lighting flexible conduits | Electrical socket extension unit | 1- Phase ELCB connection pictures | Bare fluorescent light pictures | Recessed down lights installation | Bollard light pictures | Light switch installation pictures | Home wiring pictures | Electric Meters | Electrical Grounding Electrode Pictures | Most Basic Principles of House Wiring | MATV antenna bracket pictures
=================
This layout is very old.
At least 30 years old or more.
You can see that by the number of electric socket outlet in the bedrooms and the kitchen.
A modern bedroom would need at least a few sockets in each room. You would need one for the table clock, table lamp, a television maybe, etc etc.
One electrical socket as shown in the electrical layout would definitely be not enough.
Whereas in the kitchen there is only one, and one at the dining space. The one at the kitchen area was provided for the refrigerator.
So this design IS VERY OLD.
However, I believe there are still great many areas in the world that still lack even the basic supply of household electricity.
So this simple house electrical design is still useful to great many people.
In fact, this design is more relevant. It is also more easily understood.
The single line diagram in Diagram 2 below comes together with the electrical layout in Diagram 2.
Diagram 2 – A simple house single line diagram
This blog is for beginners in electrical works. The style used in Diagram 1 and 2 above is suitable for learners of electrical works.
I will not go into detail description of these diagrams today. I have already sent a few posts that contain detail descriptions on how to read schematic diagrams. They are scattered throughout this blog. You have to search around to find them. Sorry about that.
However, for genuine beginners, they may need to know which symbol means what in the electrical layout of Diagram 1. The meaning of the individual symbols is given in Diagram 3 below.
Diagram 3 – Schedule of legends and symbols
You can see more on electrical installation work by visiting this post, Electrical installation pictures.
Copyright http://electricalinstallationwiringpicture.blogspot.com A simple electrical installation
Diagram 1 – Simple house electrical layout
=================
RELATED ARTICLES: Lighting flexible conduits | Electrical socket extension unit | 1- Phase ELCB connection pictures | Bare fluorescent light pictures | Recessed down lights installation | Bollard light pictures | Light switch installation pictures | Home wiring pictures | Electric Meters | Electrical Grounding Electrode Pictures | Most Basic Principles of House Wiring | MATV antenna bracket pictures
=================
This layout is very old.
At least 30 years old or more.
You can see that by the number of electric socket outlet in the bedrooms and the kitchen.
A modern bedroom would need at least a few sockets in each room. You would need one for the table clock, table lamp, a television maybe, etc etc.
One electrical socket as shown in the electrical layout would definitely be not enough.
Whereas in the kitchen there is only one, and one at the dining space. The one at the kitchen area was provided for the refrigerator.
So this design IS VERY OLD.
However, I believe there are still great many areas in the world that still lack even the basic supply of household electricity.
So this simple house electrical design is still useful to great many people.
In fact, this design is more relevant. It is also more easily understood.
The single line diagram in Diagram 2 below comes together with the electrical layout in Diagram 2.
Diagram 2 – A simple house single line diagram
This blog is for beginners in electrical works. The style used in Diagram 1 and 2 above is suitable for learners of electrical works.
I will not go into detail description of these diagrams today. I have already sent a few posts that contain detail descriptions on how to read schematic diagrams. They are scattered throughout this blog. You have to search around to find them. Sorry about that.
However, for genuine beginners, they may need to know which symbol means what in the electrical layout of Diagram 1. The meaning of the individual symbols is given in Diagram 3 below.
Diagram 3 – Schedule of legends and symbols
You can see more on electrical installation work by visiting this post, Electrical installation pictures.
Copyright http://electricalinstallationwiringpicture.blogspot.com A simple electrical installation
Sunday, May 9, 2010
Temporary electrical distribution
Would you believe it if I say that the picture below is a distribution system for a temporary electrical supply at a building under construction?
Picture 1 – A method(?) for a temporary electrical distribution
===== RELATED ARTICLES:
===========
I have been away for a few days. So I cannot write long posts yet.
Therefore, I will only give you pictures for a while. You have to interpret what they mean.
I took the above picture quite a while back. I thought I was interesting.
This distribution system was supplied from a temporary electrical panel nearby (see Picture 2 below).
Picture 2 – Temporary electrical panel
I was wondering why the worker needed to create such a distribution “harness”.
But I guess the answer was clear.
Notice the burn marks on one of the socket outlet at the temporary electrical panel (see Picture 3 below).
Picture 3 – Damaged electrical socket
A clearer view of the damaged outlet can be seen in Picture 4 below.
Picture 4 – Clearer view of the temporary socket outlets
You can see more pictures of electrical installations at this post, Temporary electrical installation pictures.
Copyright http://electricalinstallationwiringpicture.blogspot.com Temporary electrical distribution
Picture 1 – A method(?) for a temporary electrical distribution
===== RELATED ARTICLES:
===========
I have been away for a few days. So I cannot write long posts yet.
Therefore, I will only give you pictures for a while. You have to interpret what they mean.
I took the above picture quite a while back. I thought I was interesting.
This distribution system was supplied from a temporary electrical panel nearby (see Picture 2 below).
Picture 2 – Temporary electrical panel
I was wondering why the worker needed to create such a distribution “harness”.
But I guess the answer was clear.
Notice the burn marks on one of the socket outlet at the temporary electrical panel (see Picture 3 below).
Picture 3 – Damaged electrical socket
A clearer view of the damaged outlet can be seen in Picture 4 below.
Picture 4 – Clearer view of the temporary socket outlets
You can see more pictures of electrical installations at this post, Temporary electrical installation pictures.
Copyright http://electricalinstallationwiringpicture.blogspot.com Temporary electrical distribution
Wednesday, April 28, 2010
Electrical socket extension unit
Have you ever wondered how it looks inside the extension unit of electrical power socket? The following few pictures can help you appreciate what is going on inside this piece of common household items.
Picture 1 – The inside view of the electrical socket extension unit
=================
RELATED ARTICLES: Lighting flexible conduits | Weatherproof 13A switched sockets | Metal-clad socket outlets | A simple electrical installation | 1- Phase ELCB connection pictures | Bare fluorescent light pictures | Recessed down lights installation | Bollard light pictures | Light switch installation pictures | Home wiring pictures | Electric Meters | Electrical Grounding Electrode Pictures | Most Basic Principles of House Wiring | MATV antenna bracket pictures | Temporary socket outlet pictures | Electrical installation pictures
=================
I think most readers can understand this picture clearly with the labels that I added.
For the absolute beginners that need explanations on what does what in this picture, let me just give brief descriptions.
Extension cord
I guess everyone knows this part. The extension cable has a three-pin plug at the other end of it. It is the plug that you insert into the wall socket.
Look at Picture 7 below to see the complete set of the extension socket and plug.
Extension cables
The extension cable that you see actually has three insulated cables inside it: the LIVE cable, the NEUTRAL cable and the EARTH cable.
Each of the three cables has their own color-coded insulation: Brown for LIVE; Blue for NEUTRAL and Green with yellow stripes for EARTH.
When you work on the connections of these cables, you have to make sure not to connect them in a wrong way.
If you connect in a wrong way, the electrical appliance that takes power from this extension sockets may still work.
For example, you mistakenly swap the connections of the blue and the brown cables.
However, the ON/OFF switch (the red colored piece in Picture 1) is located at the LIVE connection. Therefore, there is still a voltage going to the appliance connected to the socket.
Cable termination screws
There are 3 cables coming from the extension cord. So you have three connection points and therefore 3 connection screws.
The connection screw may seem simple enough, but not using it properly has been the cause of many house fires all over the world. See Picture 2 below for a closer view.
Picture 2 – Cable termination screws
This is one of the biggest problems with house electrical wiring: the electrical parts look simple enough that everybody thinks they can handle it.
Yes, it is easy. But you must know enough about how the electrical components works to be able to handle it SAFELY.
If you do your own wiring, and you happen to replace an extension cord like one in the picture, make sure the connection of the copper conductor to the termination screw is strong and tight.
If the connection is not tight, then connection surfaces between the copper conductor and the screw present a high resistance to the current flow when the electrical appliance is turned on.
This high resistance will cause a high-energy loss at the connection, which is dissipated in the form of heat.
Over time, if the appliance is in operation long enough, the extension socket unit may overheat and become a source of fire.
A combustible material nearby such as a window curtain, old newspapers, even carpets and rugs may catch fire.
That is how a house electrical fire can get started. It is one of the most common cause also.
LIVE and NEUTRAL busbars
Picture 3 below gives a better view of the three busbars.
Picture 3 – Busbar connections
As the cables are connected to the termination screws from the right side, the busbars are connected from the right side.
I know there are readers who are not very familiar with the word “busbar”. So let me just spend a few words on this part.
The purpose of a busbar is similar to electrical cables, which is to carry electric current.
In cables, we normally put insulation over the current carrying conductor. The reason to prevent touching of the conductor with other things and parts nearby.
However, at some places, there is already a very good place allocated to install the current carrying conductor. So the insulation may not be necessary.
The copper conductors inside the cables are flexible. This way it is easier to handle and bend around things.
However, making things flexible from metal materials cost money.
If at certain locations, the flexibility of the copper conductor is not necessary, then why waste money by using the flexible type, right?
Another advantage of using a solid conductor like busbar is that it is easier to make connection to it. In this case, multiple connections need to be made depending on how many socket points are needed.
I think the above description is enough to show what a busbar is.
It is “solid”, so it is a “bar”.
“Bus”? I am not that sure myself exactly why the this word is used here.
All the while, I only guessed that this word is used because in the old days, a “bus” is used to denote a main path, or a main road. That is where you could wait for a transport to go long distance.
You can also get the bus by waiting anywhere along the main road. My guess is that the public did not need to wait at the bus station or the “bus stop”.
That was the “bus transport”. This is the “bus bar”.
You can get power anywhere along the conductor part. There is no need to cut anything, or go to a terminal screw.
I am only guessing here. Your own guess is just as good as mine.
Now let’s go to the next component.
ON/OFF switch
Everybody knows what an ON/OFF switch is. It is exactly what the name says.
But there is one more component related to this on-off switch. It is called the pilot light.
Picture 4 – The pilot light
In picture above, the pilot light is labeled. When the on-off switch of a particular socket unit is switched on, this light turns on.
Trivial as it seems, this feature has a very important safety purpose on an electrical socket.
When the light is on, you know there is power going into your electrical appliance. Even when the appliance is not operating (maybe because the appliance built-in on-off swith has been turned off, or the equipment has a blown fuse), you know the power is there.
It is therefore still dangerous.
The pilot light helps train our habits about safety.
When it is ON, there is DANGER for sure. There is no way we can pretend the switch on the socket is OFF.
The pilot lamp is connected in parallel with the appliance (to be connected). So even when the appliance power cord is broken, the pilot lamp lights up when the socket switch is ON.
The earth connection piece
Please observe in Picture 4 above the connection pieces from all three busbars in side the pin sockets.
Notice that while inside the “LIVE pin socket” and the “NEUTRAL pin socket” the connection to the plugs pins are made using a separate piece, the connection piece inside the “EARTH pin socket” is NOT A SEPARATE PIECE.
Why?
Because it is EXTREMELY IMPORTANT that the grounding connection from the appliance to the electrical grounding system MUST NEVER FAIL.
Therefore, the connection piece for the earth pin is part of the earth busbar.
Both is made from one solid piece of conductor and then bent around to form the earth busbar and the earth contacts (three sets of earth contacts actually, because there are three socket outlets in this socket extension unit).
Picture 5 below shows how the plug pins are inserted into the sockets.
Picture 5 – 13A sockets and a plug
Picture 6 and 7 below just show the whole assembly for readers who need them.
Picture 6 – The cover for the cable termination compartment removed
Picture 7 – The whole 13A socket extension assembly
I will see you again in the next post.
Copyright http://electricalinstallationwiringpicture.blogspot.com Electrical socket extension unit
Picture 1 – The inside view of the electrical socket extension unit
=================
RELATED ARTICLES: Lighting flexible conduits | Weatherproof 13A switched sockets | Metal-clad socket outlets | A simple electrical installation | 1- Phase ELCB connection pictures | Bare fluorescent light pictures | Recessed down lights installation | Bollard light pictures | Light switch installation pictures | Home wiring pictures | Electric Meters | Electrical Grounding Electrode Pictures | Most Basic Principles of House Wiring | MATV antenna bracket pictures | Temporary socket outlet pictures | Electrical installation pictures
=================
I think most readers can understand this picture clearly with the labels that I added.
For the absolute beginners that need explanations on what does what in this picture, let me just give brief descriptions.
Extension cord
I guess everyone knows this part. The extension cable has a three-pin plug at the other end of it. It is the plug that you insert into the wall socket.
Look at Picture 7 below to see the complete set of the extension socket and plug.
Extension cables
The extension cable that you see actually has three insulated cables inside it: the LIVE cable, the NEUTRAL cable and the EARTH cable.
Each of the three cables has their own color-coded insulation: Brown for LIVE; Blue for NEUTRAL and Green with yellow stripes for EARTH.
When you work on the connections of these cables, you have to make sure not to connect them in a wrong way.
If you connect in a wrong way, the electrical appliance that takes power from this extension sockets may still work.
For example, you mistakenly swap the connections of the blue and the brown cables.
However, the ON/OFF switch (the red colored piece in Picture 1) is located at the LIVE connection. Therefore, there is still a voltage going to the appliance connected to the socket.
Cable termination screws
There are 3 cables coming from the extension cord. So you have three connection points and therefore 3 connection screws.
The connection screw may seem simple enough, but not using it properly has been the cause of many house fires all over the world. See Picture 2 below for a closer view.
Picture 2 – Cable termination screws
This is one of the biggest problems with house electrical wiring: the electrical parts look simple enough that everybody thinks they can handle it.
Yes, it is easy. But you must know enough about how the electrical components works to be able to handle it SAFELY.
If you do your own wiring, and you happen to replace an extension cord like one in the picture, make sure the connection of the copper conductor to the termination screw is strong and tight.
If the connection is not tight, then connection surfaces between the copper conductor and the screw present a high resistance to the current flow when the electrical appliance is turned on.
This high resistance will cause a high-energy loss at the connection, which is dissipated in the form of heat.
Over time, if the appliance is in operation long enough, the extension socket unit may overheat and become a source of fire.
A combustible material nearby such as a window curtain, old newspapers, even carpets and rugs may catch fire.
That is how a house electrical fire can get started. It is one of the most common cause also.
LIVE and NEUTRAL busbars
Picture 3 below gives a better view of the three busbars.
Picture 3 – Busbar connections
As the cables are connected to the termination screws from the right side, the busbars are connected from the right side.
I know there are readers who are not very familiar with the word “busbar”. So let me just spend a few words on this part.
The purpose of a busbar is similar to electrical cables, which is to carry electric current.
In cables, we normally put insulation over the current carrying conductor. The reason to prevent touching of the conductor with other things and parts nearby.
However, at some places, there is already a very good place allocated to install the current carrying conductor. So the insulation may not be necessary.
The copper conductors inside the cables are flexible. This way it is easier to handle and bend around things.
However, making things flexible from metal materials cost money.
If at certain locations, the flexibility of the copper conductor is not necessary, then why waste money by using the flexible type, right?
Another advantage of using a solid conductor like busbar is that it is easier to make connection to it. In this case, multiple connections need to be made depending on how many socket points are needed.
I think the above description is enough to show what a busbar is.
It is “solid”, so it is a “bar”.
“Bus”? I am not that sure myself exactly why the this word is used here.
All the while, I only guessed that this word is used because in the old days, a “bus” is used to denote a main path, or a main road. That is where you could wait for a transport to go long distance.
You can also get the bus by waiting anywhere along the main road. My guess is that the public did not need to wait at the bus station or the “bus stop”.
That was the “bus transport”. This is the “bus bar”.
You can get power anywhere along the conductor part. There is no need to cut anything, or go to a terminal screw.
I am only guessing here. Your own guess is just as good as mine.
Now let’s go to the next component.
ON/OFF switch
Everybody knows what an ON/OFF switch is. It is exactly what the name says.
But there is one more component related to this on-off switch. It is called the pilot light.
Picture 4 – The pilot light
In picture above, the pilot light is labeled. When the on-off switch of a particular socket unit is switched on, this light turns on.
Trivial as it seems, this feature has a very important safety purpose on an electrical socket.
When the light is on, you know there is power going into your electrical appliance. Even when the appliance is not operating (maybe because the appliance built-in on-off swith has been turned off, or the equipment has a blown fuse), you know the power is there.
It is therefore still dangerous.
The pilot light helps train our habits about safety.
When it is ON, there is DANGER for sure. There is no way we can pretend the switch on the socket is OFF.
The pilot lamp is connected in parallel with the appliance (to be connected). So even when the appliance power cord is broken, the pilot lamp lights up when the socket switch is ON.
The earth connection piece
Please observe in Picture 4 above the connection pieces from all three busbars in side the pin sockets.
Notice that while inside the “LIVE pin socket” and the “NEUTRAL pin socket” the connection to the plugs pins are made using a separate piece, the connection piece inside the “EARTH pin socket” is NOT A SEPARATE PIECE.
Why?
Because it is EXTREMELY IMPORTANT that the grounding connection from the appliance to the electrical grounding system MUST NEVER FAIL.
Therefore, the connection piece for the earth pin is part of the earth busbar.
Both is made from one solid piece of conductor and then bent around to form the earth busbar and the earth contacts (three sets of earth contacts actually, because there are three socket outlets in this socket extension unit).
Picture 5 below shows how the plug pins are inserted into the sockets.
Picture 5 – 13A sockets and a plug
Picture 6 and 7 below just show the whole assembly for readers who need them.
Picture 6 – The cover for the cable termination compartment removed
Picture 7 – The whole 13A socket extension assembly
I will see you again in the next post.
Copyright http://electricalinstallationwiringpicture.blogspot.com Electrical socket extension unit
Monday, April 26, 2010
Feeder pillar hazard pictures
I think anybody with even a minimal amount of knowledge on the hazards presented by electrical equipment installed in public places know what is wrong with the feeder pillars in the picture below.
Picture 1 – Wrongly designed feeder pillar??
================ RELATED ARTICLES: Electric Cable Drum Pictures | Underground street light cables | Compound lighting storage yard | Feeder pillar single line diagram | Bollard light pictures | Compound Lighting Installation Pictures | Compound lighting foundation size | Electrical installation pictures | Architectural Lighting
================
I always avoid criticizing other people’s electrical designs based on evidence that is seen after installation has been completed because the outcome of a completed electrical installation is the products of many variables and factors.
Especially with the popularity of design-and-build and turnkeys types of contracts.
In these types of contracts, the main contractor is the boss and the employer of the professional consultants.
How professional can a consultant-engineer be when his paymaster is the main contractor?
Now let us get back to the picture above.
I do not know if the above electrical feeder pillars were constructed in a turnkey contract or not. I only passed by the area to find a place to eat.
However, the sight of these lovely feeder pillars caught my attention while I was looking for a parking space.
What is wrong with these feeder pillars?
I am not talking about age of the feeder pillars.
I know that everything gets old some day. Machines get worn out, the materials get deteriorated and the lovely paintwork fades out.
They do get old, just like us.
However, machines and equipment that can endanger people especially children should be designed and installed with safety as the most important criteria.
The feeder pillars above have failed in that respect. Look at Picture 2 below.
Picture 2 – Inadequate protection against electric shocks
Here you can see a hole at the feeder pillar front door.
The brownish rectangular material at the feeder pillar front door can only mean one thing: there is a kilowatt-hour (KWh) meter inside it.
The brownish material used to be a transparent material so someone could read the reading of the energy meter.
It is a usual practice to install a separate meter for the lighting of public spaces at a private compound because the owner or the property management could apply for a lower tariff on the electricity used by the carpark lights or road lights.
The feeder pillar that supplies the public lighting is where the authority KWh meter is installed.
At many installations, the design of these feeder pillars as shown in the above pictures should be adequate. It is actually one of the standard designs and therefore this design is widely used.
However, these particular feeder pillars were installed at open public spaces with open to public carpark and a number of recreational spots nearby.
In other words, now and then this place is crowded with children.
The design of the feeder pillars as installed here in the picture is wrong and dangerous
How should it be designed?
I will post a diagram of how it should be in another post. Maybe a picture or two of actual installations if I can steal a few hours to go take the pictures.
For now let me just point out a few points:
1: the front doors of the feeder pillars should be done in two layers, both having sufficient weatherproofing qualities.
The inside door protects the components inside the feeder pillar. The kilowatt-hour meter can also be installed behind this inner door.
If that is the choice, then a waterproofed viewing glass window needs to be provided at the inner door, and it should be at close distance to the meter dial.
The second layer of the feeder pillar door is the outer door. This door also has a glass-viewing window (the second layer of glass windows) directly in front of the inner viewing window.
The primary purpose of the outer door is to serve as an outer barricade against access to live parts if the outer viewing glass gets broken for whatever reason. Because of that, it is preferable if sufficient gap is provided between the outer and the inner doors. This will result in a more effective barricade.
2: The viewing windows for the kilowatt-hour meters should be of the correct materials.
Every time I looked at the feeder pillars in the above pictures, I always wonder about the cause of the damaged viewing windows.
Was it vandalism?
Or maybe it was the employees of the electricity supply company who broke the viewing window? With the windows turning so brownish, how could the “meter readers” (this is what we call the public utility workers who come to read the electricity meters and issue the bills for the month) read the readings?
But then the viewing window of the second feeder pillar was not broken. Maybe the door of this one was not locked so there was no need to break it.
It does not matter who did it. When it comes to safety of the members of the public especially children, the design and installation people in electrical installation works should ensure that the completed works is adequately safe.
Why do I put so much emphasize on children?
Because they are curious little creatures.
When they see holes like one in Picture 2 above, someday one of them may be tempted to put his hand inside.
Enough said.
I will see you again in the next post.
Copyright http://electricalinstallationwiringpicture.blogspot.com Feeder pillar hazard pictures
Picture 1 – Wrongly designed feeder pillar??
================ RELATED ARTICLES: Electric Cable Drum Pictures | Underground street light cables | Compound lighting storage yard | Feeder pillar single line diagram | Bollard light pictures | Compound Lighting Installation Pictures | Compound lighting foundation size | Electrical installation pictures | Architectural Lighting
================
I always avoid criticizing other people’s electrical designs based on evidence that is seen after installation has been completed because the outcome of a completed electrical installation is the products of many variables and factors.
Especially with the popularity of design-and-build and turnkeys types of contracts.
In these types of contracts, the main contractor is the boss and the employer of the professional consultants.
How professional can a consultant-engineer be when his paymaster is the main contractor?
Now let us get back to the picture above.
I do not know if the above electrical feeder pillars were constructed in a turnkey contract or not. I only passed by the area to find a place to eat.
However, the sight of these lovely feeder pillars caught my attention while I was looking for a parking space.
What is wrong with these feeder pillars?
I am not talking about age of the feeder pillars.
I know that everything gets old some day. Machines get worn out, the materials get deteriorated and the lovely paintwork fades out.
They do get old, just like us.
However, machines and equipment that can endanger people especially children should be designed and installed with safety as the most important criteria.
The feeder pillars above have failed in that respect. Look at Picture 2 below.
Picture 2 – Inadequate protection against electric shocks
Here you can see a hole at the feeder pillar front door.
The brownish rectangular material at the feeder pillar front door can only mean one thing: there is a kilowatt-hour (KWh) meter inside it.
The brownish material used to be a transparent material so someone could read the reading of the energy meter.
It is a usual practice to install a separate meter for the lighting of public spaces at a private compound because the owner or the property management could apply for a lower tariff on the electricity used by the carpark lights or road lights.
The feeder pillar that supplies the public lighting is where the authority KWh meter is installed.
At many installations, the design of these feeder pillars as shown in the above pictures should be adequate. It is actually one of the standard designs and therefore this design is widely used.
However, these particular feeder pillars were installed at open public spaces with open to public carpark and a number of recreational spots nearby.
In other words, now and then this place is crowded with children.
The design of the feeder pillars as installed here in the picture is wrong and dangerous
How should it be designed?
I will post a diagram of how it should be in another post. Maybe a picture or two of actual installations if I can steal a few hours to go take the pictures.
For now let me just point out a few points:
1: the front doors of the feeder pillars should be done in two layers, both having sufficient weatherproofing qualities.
The inside door protects the components inside the feeder pillar. The kilowatt-hour meter can also be installed behind this inner door.
If that is the choice, then a waterproofed viewing glass window needs to be provided at the inner door, and it should be at close distance to the meter dial.
The second layer of the feeder pillar door is the outer door. This door also has a glass-viewing window (the second layer of glass windows) directly in front of the inner viewing window.
The primary purpose of the outer door is to serve as an outer barricade against access to live parts if the outer viewing glass gets broken for whatever reason. Because of that, it is preferable if sufficient gap is provided between the outer and the inner doors. This will result in a more effective barricade.
2: The viewing windows for the kilowatt-hour meters should be of the correct materials.
Every time I looked at the feeder pillars in the above pictures, I always wonder about the cause of the damaged viewing windows.
Was it vandalism?
Or maybe it was the employees of the electricity supply company who broke the viewing window? With the windows turning so brownish, how could the “meter readers” (this is what we call the public utility workers who come to read the electricity meters and issue the bills for the month) read the readings?
But then the viewing window of the second feeder pillar was not broken. Maybe the door of this one was not locked so there was no need to break it.
It does not matter who did it. When it comes to safety of the members of the public especially children, the design and installation people in electrical installation works should ensure that the completed works is adequately safe.
Why do I put so much emphasize on children?
Because they are curious little creatures.
When they see holes like one in Picture 2 above, someday one of them may be tempted to put his hand inside.
Enough said.
I will see you again in the next post.
Copyright http://electricalinstallationwiringpicture.blogspot.com Feeder pillar hazard pictures