( V2 )

Current

( A )

8。00 a。m 461 69 12 223 3。36

9。00 a。m 677 101 11。7 220 3。4

10。00 a。m 846 126 11。6 216 3。47

11。00 a。m 950 142 11。4 217 3。45

12。00 noon 982 147 11。3 217 3。46

1。00 p。m 930 139 11 216 3。47

2。00 p。m 843 126 10。9 213 3。52

3。00 p。m 620 92 10。7 210 3。57

4。00 p。m 322 48 10。7 210 3。57

5。00 p。m 340 51 10。5 211 3。55

TABLE VII。 RESULT FOR PH LEVEL AND SALT LEVEL

Test Characteristics Before Desalination After Desalination

pH level 8。1 7

Salt level 0。8 0

TABLE VIII。 SALT LEVEL BASE MEASUREMENT

I。CONCLUSIONS

This project has completed successfully where  both of the systems which are the solar system and the desalination system have functioned properly。 This project will  benefit rural areas where are still lacking of fresh water  supply。 Further researches will be further developed to increase the efficiency of this system and reduce its operating cost。 In the near future, depleting fossil fuel and increasing need for irrigation will crucially require fresh water supply by using renewable energy systems。 The most potential renewable sources are solar and geothermal energy。 Even though current seawater desalination applications have been using solar thermal energy, solar powered devices can be integrated to the system to supply electricity for rural areas。 This research can be further developed by integrating the suggested desalination system in this paper with large-scale desalination plants, such as Multi Effect (ME) or Multi Stage Filtration (MSF), to reach reasonable operating cost and high efficiency; which can be a new solution amongst current critical issues and in the future。摘要：目前偏远地区的人们的日常用水需求仍然超过了纯净和新鲜的水的供应量。然而，这种限制为绿色技术去满足人们的需求和短缺提供了机会。利用丰富的太阳能资源和海水，人们可以实现海水的淡化来制取纯净和新鲜的饮用水，从而实现他们的梦想。本文选取了位于玻璃市的利用太阳能实现海水淡化的优化设计方案。这种可靠的低消耗的蒸馏过程被利用在离线型的电力系统。