In recent times, electric power grids in India have become bigger and complex due to the increasing demands in power supply which complicates the power flow within and between the grids. As a result, the control of power flow has become more important than ever. This is where a Phase-shifting transformer comes to the rescue. Though there are few other control measures, the installation of PST has proven to be more economical and efficient.
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Have you ever thought about how the power generated from a source several miles away reaches your premise? Well, the generated power from the power generating stations reaches a substation where it is stepped up for high voltage, transmitted through transmission lines, reaches another substation where the voltage is stepped down and is supplied to homes and businesses using low voltage distribution lines.
Say 100MW power is generated in a power station and it is transmitted through two parallel transmission lines carrying 50W each. Now say line 2 is in an overload situation, then the load in line 2 is reduced to 27MW, and the load in line 1 is increased to 73MW. This customized load sharing is done by the phase-shifting transformer or PST. A phase-shifting transformer also mitigates unwanted power transfer and improves operating performance.
A Phase-shifting transformer (PST) is a special type of transformer used to control the flow of power in the electric transmission networks. PSTs control and perfectly regulate the load sharing in parallel lines independently of the generation. They are cost-effective means for reliable and efficient power flow management and grid asset management in complex grids.
The Power flow through a line is directly proportional to the sine of the phase angle difference of the voltage between the transmitting and receiving end of the line. So a shift in phase angle in the sending or receiving circuit will change the power flow in the line.
In a PST, there are two transformers – a shunt unit connected in parallel with the line and a series unit connected in series with the line. The shunt unit causes a 90° phase difference and is fed to the series unit, where it adds up the phase-shifted power to the line thus resulting in the desired power flow in the receiving end.
The phase-shifting transformers are extensively used in massive power grids to ensure reliability and stability and allow the increased utilization of renewable energy.
Are you here because you have a plan of purchasing a phase-shifting transformer? Don’t worry if you have no clue regarding the technical terminologies mentioned above. Leave it to us. This blog post lists out 5 rules that you need to consider before buying a phase-shifting transformer. Once you check box all these, then you are good to go.
First and foremost, it is essential to consider the actual objective of your phase-shifting transformer. This is determined by how and where the transformer will be installed and what is required to serve its purpose. Having a clear-cut objective will help you quickly sort out the right set of transformers out of which you can pick the best match. When you are not clear of your purpose, you will lose out huge money purchasing the wrong one.
Therefore, Rule 1: Yes, I know what I am looking for and why. (Say Yes or no).
There are many types of phase-shifting transformers available out there.
Each type of PSTs has its characteristics and suits different applications. The indirect configuration offers an easier modular design, but the overall cost is higher than the direct type. The asymmetrical type is relatively simple compared to the symmetrical PST but changes the voltage amplitude. Therefore, it is crucial to match your requirements with the type of configuration needed.
Rule 2: I know my requirements, and what configuration is needed to fulfill them. (Say Yes or no).
Do you need a single-phase or three-phase PST?
A single-phase transformer has 2 lines of AC (1 conducting wire and 1 neutral) and a three-phase transformer has 3 lines of AC (three conducting wires and 1 neutral if needed). Three-phase transformers better accommodate loads. In general, a single-phase transformer is preferred for small operations. If there are more loads for operation, then a three-phase transformer may help to keep up. Again the decision depends on the equipment to which the transformer is connected.
Rule 3: Hope you know what phase you need! Don’t you? (Say Yes or no).
It is important to keep your voltage requirement in mind before making the purchase. You need to buy a transformer with a voltage rating that is not less than 80% of the voltage requirement of your application. In PSTs, the phase angle plays a significant role. Choosing the transformer with the required load phase angle will determine the extent to which the power flow can be controlled.
Rule 4: What is the input-output voltage you need? Can you answer it? (Say Yes or no).
PSTs are highly specialized pieces of equipment, with more windings and tap changers than traditional power transformers and a large number of connections between the three phases. This implies that they require a lot of space. If you are not sure if the transformer will fit, you can ask the manufacturer if any customization is possible. Also, ensure if high-quality core materials and precise manufacturing processes are carried out to achieve lower noise levels.
Rule 5: Do you have a lot of space to accommodate PST? (Say Yes or no).
As you can see, phase-shifting transformers can go a long way in sustaining the power grids by avoiding system overloads and instabilities and also help in the reduction of operating costs. We believe that the above rules will help you choose the right PST for your business. Did you answer ‘yes’ to most questions, then you are good to go. If not, you will have to know your requirements before making a purchase.
If you still feel doubtful, we in EVR Electricals are here to help. Our well-experienced sales team will assist you in picking the perfect PST that matches your requirements.
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EVR Electricals phase-shifting transformers are manufactured exquisitely to avoid system overloads and instabilities, increase the transmission capacity, and protect high-voltage equipment from thermal overload. We do offer other different kinds of transformers such as distribution transformers, Small power transformers, Isolation/Ultra isolation transformers, converter/Inverter transformers, etc.
Do you think you have a point to add up to this list? Feel free to leave a comment below! Have an amazing day!
Extremely low frequency EMFs index » Overview | Power lines | Substations | Electrical wiring | Electrical appliances
Substations are part of the electricity supply network that enables the widespread use of electricity at home, work, places for education, leisure, commerce, health care, etc. The size of substations can be very variable, depending on whether they serve mainly residential properties, or also commercial and industrial units, etc. Schools and institutions such as hospitals often have their own substation. The purpose of substations is to transform the voltage from long-distance high voltage powerlines to the voltages used to supply our homes.
Electric and magnetic fields are generated by the equipment inside the substation or transformer and the cables going in and out. Sometimes substations are interconnected in such a way that high magnetic field levels are created in a wide area, affecting many houses, especially those with small or no front gardens. Again, the only way to know what field levels you are exposed to is to measure them - is it impossible to give an accurate calculation or estimation.
Low power substations are found about 150-200 metres apart in a typical urban area. They are often grey metal boxes in a fenced enclosure. Sometimes they are inside brick or plastic structures. They have a 'Danger of Death' yellow sign attached to the fence. This is to warn the public of the danger of electric shocks. They change a high voltage coming into the substation, often 11,000 volts, though it can be higher, into 415/230 volts. Rural areas may have small grey box transformers attached part way up a wooden pole. The bigger the substation, the higher the electromagnetic fields are likely to be and the further away a property has to be, to be in low fields. Measure the fields, it is easy and vital to do so.
Substations are not hazardous because they are substations. It is because they are surrounded by electromagnetic fields that the equipment and cables they contain produce, that they have to be treated with caution. Measured electromagnetic fields such as those produced by substations have been associated with health effects such as cancer, depression, dementia, infertility, miscarriage, heart problems, etc. For further details see our library article Powerfrequency EMFs and Health.
There are two types of electromagnetic fields produced by overhead and underground cables and the substation equipment itself; electric fields and magnetic fields. The strength of the electric field depends on the voltage. Electric fields from substation equipment are unlikely to extend beyond the equipment housing, as they are screened by practically all building materials. Magnetic fields are caused by electric current flowing when people use electrical power. For all practical purposes magnetic fields cannot be stopped and will travel through walls as if they were not there.
Larger substations are associated with higher EMFs. The nearer they are to a property, the higher the levels of magnetic fields are likely to be inside.
EMFs can be measured using a hand-held, easy-to-use meter such as the EMFields-ELF or the smaller MagneMeter available to hire or purchase from EMFields.
Building materials and some trees reduce electric fields, but magnetic fields travel through pretty well everything.
There may also be underground cables leading to or away from the transformers. Electric and magnetic fields also come from underground cables. The electric fields will be zero as they are screened by earth, concrete, sand etc. The magnetic fields are very high near to the cable, higher than from overhead cables because they are closer to you. They fall off more rapidly than the fields from overhead wires, because the cables are closer together and cancel out each other's effects more quickly. You are likely to have a cable running underground at the front of your property, which can affect electromagnetic fields at the front of the house, or at the side or back, especially if you have a public footpath by the side of your property. This could give you high levels of electromagnetic fields in the garden.
Houses, or ground floor or basement flats, with very small or no front garden, may have high magnetic fields in their front rooms from distribution cables running underneath the pavement. In many built up areas the electricity companies often connect neutrals from different substations together, this can produce unpredictable 'net currents' which flow round the system the wrong way and can give rise to high magnetic fields over wide areas (e.g. round 4 or 5 streets). It can create very high magnetic fields in houses, usually with no way of reducing them, as the electricity companies do not believe high magnetic fields are a problem. The ONLY way to find out if this is a problem is to measure the magnetic fields at the house, preferably at a "busy"time - e.g. 8 am or 6 pm. If the electricity company takes readings for you (in some areas this is a possibility), they may not be taking readings at these peak times.
If there is a 'net current' in the street, the magnetic field levels will be similar throughout the property, and most of the other nearby houses, not reducing much with distance from the substation. In our surveys about one quarter of the properties can have net current problems. Please see the links to SAGE2 report lower down this page for further detailed information.
'Stray' currents are due to faults in the neighbourhood electricity system that have transferred on to metal gas and/or water pipes and can be detected by holding the EMF measurement meter close to the pipes where they come into the house. In flats, measure close to all water and gas pipes. Stray currents are surprisingly common and can be stopped, but this is not always easy and there is a cost involved.
In cities, flats, workplaces and sometimes houses can have substations next to, or under the property (in a basement), as part of the building structure. These can produce high magnetic field levels in rooms on the same floor as the substation or in the floor above (Ilonen , Thuroczy ). Magnetic fields can also cause computer 'wobble' which can make operators feel ill and is against Health and Safety at Work regulations.
Sally Sims and Peter Dent of Oxford Brookes University in published a study (400 KB file) that showed that the close presence of a substation could reduce the number of potential buyers by up to 63%, depending on the type of property concerned and the size and visibility of the substation. The study in reported that visible substations and cables reduce the value of a property; the percentage reduction depended on the type of property.
Read about the Department of Health led PW SAGE2 report and download and read the full SAGE2 report (1 MB file) which was released and sent to the Health Minister on the 8th June . That has masses of useful details about substations and what can be done to reduce EMFs from substations and associated mains electricity supply cables.
The local electricity board may provide you with a plan of underground cables, to see how close the main cables are to you. They are not always accurate, but their actual position can easily be detected using a powerfrequency field meter, such as the PRO or B, from EMFields. It is possible that the electricity company will only supply plans of cables to a property's owner, so some negotiation may be necessary if you haven't purchased the property yet.
The only way to get a reliable idea of the field from cables is to measure them. It is very difficult to calculate the estimated level because of the possible variability, due to trench size and depth and layout of the cables.
For most people, it is where you spend a lot of time relatively unmoving that it is advisable to have low fields. If there is a substation adjacent to the house it is very important to measure the field levels. Until you have done so, put any beds in the room as far as possible from the substation, with the bed-head at the furthest point. Remember the critical precautionary level for magnetic field levels (which cannot be reduced by screening) is below 0.1 microtesla in bedrooms and 0.15 microtesla in play or sitting areas. Ideally, areas in the garden, which are used for play or relaxing should have fields of less than 0.2 microtesla.
Hand-held, easy-to-use meters that will accurately measure both electric and magnetic fields such as the EMFields-ELF or magnetic fields such as the MagneMeter (microtesla or mG scales) are available to hire or buy in the UK from EMFields.
Want more information on box type substation? Feel free to contact us.