What are the benefits of geothermal technology?




Geothermal heat pumps, or ground-source heat pumps, for heating and cooling buildings are a rapidly growing example of a geothermal direct use application. The technology has developed almost without publicity in recent years to become a significant new factor in the supply equation. This is an electrically-based technology that allows high ef­ficiency, reversible, water-source heat pumps to be installed in build­ings in most geographical and geological locations (worldwide). The combination of increasing levels of electrical generation efficien­cy, with the impressive energy amplification' of geothermal heat pumps means that space heating can be delivered with effective efficiencies that exceed2 100%. The "additional" energy is supplied from the ground. In addition these systems also offer highly efficient cool­ing. The types of buildings that are using ground-source heating and cooling in this manner range from small utility or public housing, through to very large (MW-sized) institutional or commercial build-mgs. This technology can offer up to 40% reductions in C02 emissions against competing technologies. If all of the electricity is supplied from non-fossil sources, there are no C02 emissions associated with heating and cooling a building.

Recently, several large-scale arrays3 have been installed to feed larg-er systems where suitable supplies of deep geothermal water are not available. In the largest development to date, 4000 units - each with its own borehole - have been established on a US Army base in Loui-Slana to provide heating and cooling.



Section I. Power Engineerin g Unit 5. Geothermal Energy



 


The concept was developed independently in the US and Europl and, although Sweden and Switzerland have installed many thousand) of units to provide winter heating in houses, the pace of installation iJ the USA and Canada during the last fifteen years has overtakerl the European rate. There are now believed to be well over a quarter J a million installations in place in North America.

While the main activity is currently in the USA, there are a growinl number of installations in Canada, Sweden, Switzerland, Austria anq Germany. Smaller numbers are being installed in other European coun tries, and in Australia. The Geothermal Heat Pump Consortium cub rently has over 750 institutional, corporate and commercial members! and 40 international members from countries including AustraliJ Canada, China, Croatia, Finland, Germany, India, Japarl the Netherlands, Poland, Russia, Sweden, Turkey, and the UK. I

Ground-source heat pumps are perhaps the first indication oi the seventh age of geothermal technology, breaking the final barrier ol geographical availability.

To sum up: geothermal technology offers many benefits — clean! indigenous, firm energy — but suffers from economic uncertainties and geographical limitations. These problems are being actively addressed and future prospects seem bright.

1 — усиление; 2 — превышают; 3 - структуры; 4 - обогнал

IT IS INTERESTING TO KNOW

• Read and retell the text.

Multiple Use of Low Temperature Geothermal Water in Erding

Reclamation and reuse of a former gas exploration borehole wii provide geothermal water for a distinct heating system and drinking water for the town of Erding, Germany. As well as providing these di-j rect benefits to the town, implementation' of the scheme will result iru a reduction in the consumption of fossil fuels to generate energy, with! a subsequent positive impact on the environment, and reduced pres-| sure on existing supplies of drinking water.

About 552,000 cubic metres of geothermal water will be extracted from the borehole each year and cooled, using a heat exchanger an^


heat pump, from a temperature of about 65 °C to between 17 ° and 23 °C. The absorption-type heat pump is designed for two-step opera­tion, to give a high heating efficiency. The new district heating net­work, with a capacity of 17MW, will supply water, at a temperature of about 40 °C, to residential areas2, hospitals and schools. Compared to the conventional system of energy supply currently in use in Erding, the energy produced by this new scheme will replace the equivalent of 29,000 MWh per year of energy generated from fossil fuels (about 51 % of energy use). Once the district heating scheme is established, the geothermal water extracted will be purified3 and treated (by de­gassing, filtration and ozonation) for use as drinking water, which will be blended with the existing water supply.

1 — осуществление; 2 — жилые районы; 3 — очищена

• Open a round table discussion on thermal power in our country and abroad using the following questions:

What do you think of...? What is your opinion of...? Do you think that...? Do you agree that...? Is it really so?


Unit 7


Unit 7. Tidal Energy



 


TIDAL ENERGY

PARTI

• Read and translate the text below.

Over the past three decades the feasibility of using ocean tides t< generate electric power has been investigated at many sites.

Results suggest that the potential for economic development is small Of the approximately 22,000 TWh per year dissipated by the tides, 200 TWh is now considered economically recoverable and less than 0.6 TWh is produced by existing plants.

Six areas account for well over half of the potentially developabld energy:

The headwaters of the Bay of Fundy (Canada);

The Severn estuary (United Kingdom);

The Gulf of St. Malo (France);

The south-east coast of China; I

and Russian coasts bordering the White Sea and Sea of Okhotsk.

Other potentially feasible sites include the Mersey estuary and small­er sites bordering the Irish Sea and Bristol Channel (United Kingdom), the Gulf of Kachch (India), the west coast of Korea, the north-west] coast of Australia, Cook Inlet (Alaska) and the Gulf of San Jose (Ar-j gentina).

By far the largest tidal plant in service is Ranee (France), with a capacity of 240 MWand an annual output exceeding 500 GWh. Oth­ers include the 20 MW Annapolis plant in Canada, several small units1 in China with total capacity of about 5 MW and a 400 kW experimen­tal unit near Murmansk in Russia.

Most designs, existing or proposed, have opted for a single tidal ba­sin to create hydraulic heads and propeller turbines to extract energy therefrom. Linked and paired basins have also been considered. Inno­vative approaches have included extraction of energy directly from tide races using a variety of prime movers.


The main obstacle to development is economic. Capital costs are high in relation to output: a consequence of the low and variable heads available at even the best sites. Heads available at the turbine vary throughout each tidal cycle, averaging less than 70% of the maximum. As a result, installed capacity is underutilized, typical capacity factors tending to fall in the range 0.23 to 0.37. Low heads imply that civil as well as mechanical engineering components must be large in compar­ison to output. For such reasons, tidal plants are likely to be practica­ble only where energy is concentrated by large tides and where physi­cal features permit construction of tidal basins at low cost.

Significant capital-cost reductions through improved design and construction techniques have been achieved over the past three decades. In China a somewhat different approach has been taken: tidal plants have been built as part of broader schemes of resource utilization — typically land reclamation or aquaculture.

In a world increasingly sensitive to environmental factors, tidal plants must avoid unacceptable impacts. Tidal power is non-polluting and in this respect superior to thermal generation. Beyond that, it is difficult to generalize. No serious long-term impacts are known to have been caused by the Ranee tidal power plant, but large developments in the Bay of Fundy would, it has been predicted, perturb the tidal re­gime, with impacts on New England shorelines.

In recent years, commercial acceptance of combined-cycle genera­tion based on combustion turbines has reduced the potential econom­ic and environmental costs of meeting future capacity and energy de­mands through thermal plants wherever natural gas is available at competitive prices. This has tended to increase the economic bias against tidal power.

Mother development with adverse implications for tidal power is the trend in many countries to adopt market pricing of electric energy and dispense with regulatory pricing. This in almost every case entails competition in the generation function. Under such conditions, com­petitors will be under strong compulsion to choose plant types having the shortest construction times and the lowest unit capital costs.

Such factors render construction of new tidal generation capacity unlikely during the near future, unless strong incentives such as emis­sion caps or carbon taxes are imposed.

4-4661


50 Section I. Power Engineeri:


Unit 7. Tidal Energy



 


VOCABULARY

feasibility осуществимость, выпол- obstacle препятствие

нимость to imply подразумевать

to investigate исследовать to predict предсказывать

estuary дельта, устье реки to perturb нарушать

to exceed превышать bias наклон, уклон

therefrom оттуда to dispense распределять

to extract извлекать to entail влечь за собой, вызывать

innovative approach новаторский to render изменить состояние чегс
подход либо

EXERCISES

1. Give the Russian equivalents to the following English word combinations fron
the text: 1

— ocean tides

— the largest tidal plant

— annual output J

— a single tidal basin

— innovative approaches

— tide races

— mechanical engineering components

— design and construction techniques

— tidal basins

— combined-cycle generation combustion turbines

— energy demands

— new tidal generation capacity

2. Find in the text the English equivalents to the following Russian word combinations:

— экономически возместимый I

— потенциально возможные площадки станций I

— быстрое приливо-отливное течение

— малый и переменные напоры

— капитальные затраты

— усовершенствованные методы проектирования и строитель-1 ства

— выработка с комбинированным циклом


3. Translate the following sentences paying attention to the difference in form and trans­
lation between Participle I and Participle II.

a) Of the approximately 22,000 TWh per year dissipated by the tides, 200 TWh is now considered economically recoverable and less than 0.6 TWh is produced by existing plants.

b) Most designs, existing or proposed, have opted for a single tidal basin to create hydraulic heads and propeller turbines to extract energy therefrom.

c) Linked and paired basins have also been considered.

d) As a result, installed capacity is underutilized, typical capacity factors tending to fall in the range 0.23 to 0.37.

e) In recent years, commercial acceptance of combined-cycle gen­eration based on combustion turbines has reduced the potential economic and environmental costs of meeting future capacity and energy demands.

f) Under such conditions, competitors will be under strong com­
pulsion to choose plant types having the shortest construction
times and the lowest unit capital costs.

4. Read the text above and make up a list of the key words and topic sentences.

5. Read the text and say whether the statements are true or false according to the text.

 

a) Results suggest that the potential for economic development is large.

b) Five areas account for well over half of the potentially develop­able energy.

c) By far the largest tidal plant in service is Ranee (France), with a capacity of 240 MW and an annual output exceeding 500 GWh.

d) Linked and paired basins have not been considered.

e) The main obstacle to development is economic.

0 Heads available at the turbine vary throughout each tidal cycle, averaging less than 70% of the maximum.

g) Tidal power is polluting and in this respect not superior to ther­
mal generation.

b«Find the passages in the text where the following ideas are expressed. Translate the passages into Russian.

a) The feasibility of using ocean tides to generate electric power has been investigated at many sites.



Section I. Power Engineering


Unit 7. Tidal Energy



 


b) Innovative approaches have included extraction of energy directljj from tide races using a variety of prime movers.

c) Commercial acceptance of combined-cycle generation based on combustion turbines has reduced the potential economic and en-| vironmental costs.

 



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