Save energy, ‘our planet deserves no less’
20 May 2008
In this environmentally conscious era, if there was a way to cut energy losses by an amount equivalent to one per cent of all electricity consumed, surely the network operating companies (NOCs) and large users of electricity would be rushing to adopt it? Astonishingly, in Europe and America the opportunity to achieve this significant saving is largely being ignored, says Stuart Harvey of Silverteam.
Transformers are key components in every electrical distribution network. They’re used in multiple locations throughout the NOC’s systems, and large energy users such as factories and hospitals frequently have one or more power transformers of their own, usually forming part of an on-site substation.
Given the ever-present and growing need for energy efficiency, the good news is that transformers are relatively efficient. In fact, with typical modern power transformers efficiencies in excess of 97 per cent are routinely achieved, which on the face of it sounds perfectly satisfactory.
Looked at in another way, however, this figure means that up to three per cent of all electrical power generated is wasted in transformer losses. Clearly these losses are far from negligible, and anything that can be done to reduce them has the potential to deliver huge savings, not just in monetary terms, but also in terms of reduced environmental impact.
And there is a perfectly good way of cutting these losses – the use of transformers with amorphous cores.
Conventional transformers have cores assembled from stacks of laminations that are made from silicon steel with an almost uniform crystalline structure. In transformers with amorphous cores, a ribbon of steel is wound, usually into a rectangular toroid shape, to form the core. Although the material used for the core is still a form of silicon steel, it is produced in such a way that has no regular crystalline structure – hence the name amorphous, which means without structure.
The big benefit is that amorphous steel has lower hysteresis losses. Put in simple terms, this means that less energy is wasted in magnetising and demagnetising it during each cycle of the supply current. In addition, the construction of amorphous cores means that they have higher electrical resistance than conventional cores, so losses due to unwanted eddy currents in the core are also reduced.
These effects, known collectively as iron losses, are most significant in transformers that are lightly loaded, so just how important are they in practice? To answer this question, it is important to realise that transformers rarely operate at full load. In fact, because they have to be sized to handle the maximum anticipate load, most spend many hours a day very lightly loaded.
For example, a transformer supplying a factory may be, say, 70 per cent loaded during working hours, and only 10 per cent loaded during the evenings and at weekends. The variation in loading is usually expressed as a load factor that, in effect, represents the percentage of the transformer’s overall capacity to supply energy that is used over a given period – often a year.
On this basis, studies have shown that transformers used to supply factories typically have load factors around 40 per cent, while those used to supply offices, hospitals and similar premises often have load factors as low as 20 per cent.
With this in mind, let’s look at some loss data for a 550kVA transformer supplying an industrial installation with a load factor of 40 per cent. With a conventional transformer of modern design, the no-load losses were 665W, while the on-load losses were 4,400W. A 40 per cent load factor, this equates to total losses of 11,992 kWh per year. With an amorphous core transformer, the corresponding figures are 220W, 3,500W and annual losses of just 6,883 kWh.
This is a massive reduction of 5,159 kWh which, at eight pence per unit, corresponds to cash saving in excess of £400. Over the typical 30-year life of the transformer, the saving is an impressive £12,000 at today’s prices. Even more impressive is the associated reduction in CO2 emissions, which equates to almost three tonnes per year.
Finally, it’s worth noting these calculations are based on an industrial installation with a 40 per cent load factor. In commercial and residential applications where the load factor is invariably lower, even greater savings will be achieved.
If power transformers with amorphous cores have so much to offer, the big question has to be why are they not more widely used? Before answering this question, it’s important to put it in a global context. The demand for amorphous core transformers is, in fact, increasingly rapidly in many countries, including Japan, China and India. The big exceptions are Europe and America.
In these relatively conservative markets, the usual objection is that amorphous core transformers are more expensive than their conventional counterparts. There is some truth in this but, in recent years, the silicon steel used in ordinary transformers has increased in price more rapidly than the amorphous materials, so the price differential between the two types of transformer is now small.
Recent calculations have, in fact, shown that the payback period for the extra investment in an amorphous core transformer is usually in the region of three to five years. If, as it seems likely, energy prices continue to increase, this period will become even shorter.
Regrettably the problem still remains of contract being placed on the lowest initial price, often with scant regard to lifetime costs. Growing environmental concern is, however, starting to force a change in this attitude, which hopefully means the benefits of amorphous core transformers will, in the future, be more carefully taken into account when contracts are placed.
Other objections raised in connection with amorphous core transformers are that they are physically larger than conventional types, and that they generate more noise. Once again there is an element of truth behind these assertions but, with the latest amorphous materials, these differences are becoming smaller and, in particular, the noise issue is almost completely solved.
In a world where global warming is already starting to have severe consequences, no one can afford to be complacent about energy losses – least of all organisations that generate, distribute and use large amounts of electrical energy.
For these organisations, amorphous core transformers open a cost-effective route to achieving savings, which may seem small in percentage terms, but in terms of kWh of energy and tonnes of CO2 saved per year are truly enormous. Put simply, now is the time to switch to amorphous – our planet needs and deserves no less.
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