SUMMARY Water power plants and watersystems by Hákon Aðalsteinsson National Energy Authority, Grensásvegi 9, 108 Reykjavík. The generation of energy from water power is a clean process compared with the use of fossil fuels or nuclear fission. The main impact is connected with land use, changes in the nature of the lakes involved, and changed discharge charact- eristics. Every hydropower plant is composed of one or more reservoirs, dammed water- channels, tunnels and a dam at the power plant. In Iceland 4 TWh/a have been harness- ed, 12% of the most economical hydro- power (33 TWh/a), and 6% of the technic- ally reasonable hydropower (64 TWh/a). Silted glacial rivers will provide most of the economical water power planned to be developed in the near future. In most cases the hydropower plants will be at the marg- in or just below the central highland plateau, and thus affect the inhabited are- as only to a small extent. The most severe impact is the inundation of vegetated land. The sparse vegetation on the highland plateau is often in valleys or areas where the groundwater table is relatively high, and those sites often make ideal sites for reservoirs. Much effort is put into easing conflicts between hydropower plant needs and conservation of the most valuable vegetated areas. For example, recently the National Water Power Company and the Nature Conservation Council negotiated the maximum allowed elevation of a reser- voir in Þjórsárver. The situation concerning power plants in glacial rivers is rather peculiar and diff- erent from the usual problems connected with power plants. The glacial rivers are characterised by a high annual as well as diurnal fluctuation in discharge. The silt content is rather high during summer, oft'en 300—1000 mg/1. The transparency is very low in such water. Often 80-95% of the silt is sedimented in lakes with a retent- ion time of at least 100 days. The transpar- ency is still low in reservoirs with the silt content reduced to 10-30 mg/1. The invertebrates living in glacial rivers have not yet been investigated to any ex- tent, but as can be seen during low flow periods the fauna is poor because of high silt content (low transparency), bed load and fluctuating water level. The damming and retention of water will reduce the silt content and mostly eliminate the bed load and reduce the water level fluctuation of the rivers downstream from the power plants. These factors are all positive for the possibilities for algae and invertebrates to settle and thrive. On the other hand increased channel erosion, at least in the beginning, may reduce the positive effects of the above mentioned factors. The tem- perature situation is less clear. Usually temperature decreases downstream from dams, except in winter, because the water is usually tapped from the hypolimnion, which during summer is colder than the epilimnion. In winters the hypolimnion is warmer than the surface water. In Ice- landic lakes a thermocline is not developed in lakes up to at least 100 m deep because of strong wind-induced upmixing of the water. Most dams are only 10-20 m deep. Thus the temperature regime is thought to follow different lines than usually reported from rivers downstream from the dams. The temperature most likely does not increase as fast as in unregulated streams and does not reach the same high summer maximum, but keeps warm longer during the autumn. In winter it is thought to be mostly unaffected by the dam. On the whole the temperature changes are not supposed to have a serious impact on life downstream in the rivers. The most severe impact of the fluctuat- ing water level in reservoirs is usually the radical reduction of life in the strand zone within the water level amplitude. In the glacial river reservoirs this effect is enhanc- 130

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