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地热——被低估的美国主要能源

Geothermal - An Undervalued Primary U.S. Energy Source
课程网址: http://videolectures.net/mitworld_tester_gup/  
主讲教师: Jefferson W. Tester
开课单位: 麻省理工学院
开课时间: 2013-09-16
课程语种: 英语
中文简介:
尽管地热能提供了巨大的好处,但在我们目前稳定的可再生资源中,地热能仍然是一个可怜的表亲。这是杰斐逊·泰斯特在参加能源部关于开发这一潜在巨大能源库的技术和经济可行性的调查后得出的不可避免的结论。他向麻省理工学院博物馆现场和在线观众描述了能源部报告的发现。 这个由18名成员组成的研究团队接受了一个事实,即美国将需要更多的电力,刚刚通过了一百万兆瓦的里程碑。但供应系统也面临威胁,天然气价格不断上涨,煤炭生产难以扩大,更不用说输电线路和储能问题了。研究人员认为,太阳能和风能等可再生能源在未来20年内不会造成太大影响,而核能继续受到公众的抵制。 与此同时,在过去30年中,地热系统已经成功地展示了其发电能力。世界上的一些地区有着非常接近地表的蒸汽或热水(想想黄石老忠实间歇泉)。Tester说,在冰岛和美国西部地区,“我们开采的不是地下矿物,而是热能。”目前,美国生产3000兆瓦的地热电。但“并不是所有的地球上都有温泉”,Tester说,所以诀窍是“复制大自然所做的。” 在全球范围内的几次重要演示中,研究人员正在研究这种强化/工程地热系统(EEG)。他们向下钻至5公里及以上的深度,深度足以到达炽热的岩石。然后他们将水循环到这些地下蓄热器中,在那里加热到足以发电。测试人员相信,这项工作显示出巨大的潜力。 Tester的报告假设,如果地热“不仅仅是一个小小的好奇心”,那么它必须提供与当今美国核能或水电水平相当的能源——10万兆瓦。到2050年,EEG可能成为这样一个能源参与者,如果在未来15年内,政府和工业界开始进行一些现场示范——首先是在西方一些浅层、高品位的场所,这些场所将快速、经济地开始生产能源,最后,在一些需要在6公里以上深度进行更昂贵开采的地点,如美国东部,总投资6-8亿美元将低于一个清洁煤厂的成本,Tester指出。目前,与其他可再生能源项目不同,“地热在预算中没有资金。”Tester评论道,“如果我着眼于我的孩子和孙子孙女的未来,我想确保我们正在考虑所有的选择。”
课程简介: Geothermal energy remains the poor cousin in our current stable of renewable resources, in spite of offering enormous benefits. That’s Jefferson Tester’s inescapable conclusion, after participating in a Department of Energy investigation into the technical and economic viability of tapping into this potentially vast energy pool. He describes the findings of the DOE report to a live and online MIT Museum audience. The 18-member research team accepted as givens the fact that U.S. will demand ever more power, having just passed the one million megawatt milestone. But there are threats to the supply system, with increasing prices for natural gas and difficulties expanding coal production, not to mention issues around electric transmission lines and energy storage. Renewables like solar and wind won’t make much of a dent in the next 20 years, researchers believe, and nuclear power continues to meet public resistance. Meanwhile, for the last 30 years, geothermal systems have been successfully demonstrating their capacity to generate electricity. Some areas of the world are blessed with steam or hot water located fairly close to the surface (think of Yellowstone’s Old Faithful geyser). In Iceland and locations in the U.S. west, says Tester, “instead of mining minerals from the ground, we’re mining heat.” Right now, the U.S. produces 3000 megawatts of geothermal electricity. But “not all the earth is so blessed” with hot springs, says Tester, so the trick is “to replicate what nature has done.” In several critical demonstrations around the globe, researchers are working on such enhanced/engineered geothermal systems (EEGS). They drill down to depths of 5 kilometers and beyond, deep enough to reach hot rock. Then they circulate water into these underground heat reservoirs, where it warms up enough to generate electric power. The work shows great promise, Tester believes. Tester’s report assumed that if geothermal were “going to be anything more than a minor curiosity,” it would have to supply energy at the level of nuclear or hydropower in the U.S. today – 100 thousand megawatts. EEGS could become such an energy player by 2050, if in the next 15 years, government and industry kicked in for a handful of field demonstrations -- first in some shallow, high grade sites in the West, which would quickly and economically start producing energy, and then eventually in some sites requiring more expensive mining at depths greater than six kilometers -- such as in the eastern U.S. The total investment of $600-800 million would be less than the cost of a single clean coal plant, notes Tester. Currently, unlike other renewable energy projects, “geothermal has no money in the budget.” Comments Tester, “If I look to the future of my children, and my grandchildren, I’d want to make sure we’re looking at all the options.”
关 键 词: 地热能; 可再生资源; 供应系统
课程来源: 视频讲座网
数据采集: 2021-11-28:zkj
最后编审: 2021-11-28:zkj
阅读次数: 61