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环境科学科技创新导报 Science and Technology Innovation Herald136DOI:10.16660/ki.1674-098X.2020.15.136西南某水电站环境影响后评价综述张宇 张丽梅 徐天宝(中国电建集团昆明勘测设计研究院有限公司 云南昆明 650051)摘 要:水力发电为社会带来积极效益的同时,也带来了一些环境方面的问题,而且通常在项目建成运行一定时期后才能逐步显现出来。
本文对西南某水电站环境影响开展后评价研究,通过建立研究体系,识别工程建设带来的主要环境影响,对工程运行一段时间后的实际影响情况进行评价分析。
通过与环境影响预测结果的比对,对工程环境影响存在的问题提出减缓措施及建议。
关键词:水力发电 环境影响后评价 环境影响中图分类号:X82 文献标识码:A 文章编号:1674-098X(2020)05(c)-0136-02水力发电对环境的影响通常在项目建成运行一定时期后才能逐步显现出来。
随着我国水力发电众多工程的运行投产,水力发电环境影响后评价逐步成为进行后续规划布局、科学决策和管理监督的重要依据和手段。
我国西南地区拥有丰富的水能资源和水力发电容量,分析评价已建电站可能带来的环境影响,提出减缓或减免不利影响的措施和建议,对于指导西南水电的建设、环境污染防治和生态环境破坏等方面具有重要意义。
该电站位于云南省曲靖市师宗县,工程开发任务为单一发电,无农田灌溉、防洪、航运等要求。
电站装机容量为100MW ,总库容50万m 3,正常蓄水位821.00m,具有周调节性能,多年平均发电量4亿kW ·h。
1 自然环境概况工程所在区域属高中山区,区内总体地势北西高东南低,区内发育有两级剥夷面和三级阶地。
属南亚热带气候,多年平均降雨量在1468~1657mm,多年平均气温为14.8℃~18.5℃,多年平均相对湿度为81%~86%,主导风向为南西风,多年平均风速为2.8m/s。
水电站对水生生物的影响1.绪论随着社会经济发展,在河流上大规模筑坝拦截河流水量(发电,灌溉,控制洪水等),是河流生态环境受人为影响最显著、最广泛、最严重的事件之一.根据世界大坝学会的统计,目前全世界有36000座大中型水坝在运行,控制着全球20%左右的径流量。
在中国,长江、黄河等主要河流的梯级水库正快速进行,部分河流缺乏有效管理引起河流断流、水体污染等,严重影响河流生态系统的结构和功能。
大坝建设人为改变了河流原有的物质场、能量场、化学场和生物场,直接影响生源要素在河流中的生物地球化学行为(生源要素输送通量、赋存形态、组成比例等),进而改变河流生态系统的物种构成、栖息地分布以及相应的生态功能。
鉴于筑坝造成河流生源要素、河流和区域生态环境的改变,国内外科学家对河流生态系统的响应过程广泛重视,成为目前河流生态研究的重要领域之一。
水电设施及运转过程给生态带来压力,值得重视的主要影响来自两个过程,一是筑坝过程,二是取水过程。
这两大过程对河流生态系统的连通性和整体性可能造成严重影响,归结起来,主要表现在两个方面:一是改变自然水文过程,不同程度地切割生境,隔断河流廊道系统的空间连通性;二是对河流廊道在时间尺度上的自然动态造成严重干扰.两方面的胁迫影响都会导致河流生态系统的结构和功能的变化。
除了对河流生态系统造成一定影响外,对其他临近水电站的生态系统也造成了一定的影响,如水电站大坝截流造成上游大面积农田、林地被淹没,河道鱼类的活动范围受到极大的限制,阻碍了鱼类的繁衍和其它野生动物的正常活动。
大坝下游出现了大面积河道干枯,致使下游鱼类生存面临灭绝危机,野生动物饮水、迁移受到严重威胁。
水利水电工程建设阻断了河流的天然连续,改变了河流的水文情势,破坏了鱼类的栖息环境,对鱼类的影响非常严重.如,根据近些年调查统计,长江干支流四大家鱼产量在逐年下降;根据2001年对长江监利段的监测,四大家鱼产量与1981年相比,平均下61。
永德县勐板小河新边田水电站增效扩容项目环境影响报告书(报批稿)委托单位:永德星网电力开发有限公司评价单位:云南大学二〇一四年十二月前言勐板小河属怒江流域南汀河水系,是赛米河(凤尾河、南捧河)干流中上游右岸加入的一级支流,属南汀河的二级支流,发源于永德县勐板乡西北面的天神山,海拔为2195m,在永德县勐板乡小街田村附近汇入赛米河(凤尾河上游),汇口高程为955m。
河流先由西北向东南流向,于下游河段新边田村附近改由东北流向西南。
勐板小河河段落差大、河床下切侵蚀强、河谷狭窄,多呈V型河谷。
干流总河长11.23km,流域面积45.8km2,整个流域地势由西南向东北倾斜,呈扇形,流域内河网水系发育,流域平均高程为1753m;取水口以上河道总长8.8km,径流面积42.9km2,流域平均高程为1810m;厂址位于勐板小河左岸阶地上新边田村附近。
勐板小河水能资源丰富,早在1975年就在下游河段建有一座水电站——新边田水电站,引水方式为土渠径流,渠道长为3.2km,电站利用水高程100m,实用落差97m,实用流量为0.2m3/s,电站装机容量75kW×2=150kW,水轮机采用冲击式水轮机,传动方式为三角皮带传动。
该电站的建成曾为勐板乡部份村民的生产生活产生了较好的经济效益和社会效益。
但由于电站运行时间过长,设备老化严重,机组效率低下,有些零部件市场上已无法采购。
该电站正常发电至1994年后,又因渠道沿途山体滑坡渠道坍塌严重,加之机械严重磨损老化,电机动力不足,受益村民无力筹集资金对该电站及沟渠实行复修,其次电站水资源浪费严重,因此电站基本处于闲置状态。
现场调查发现,原有厂房和机组已经完全拆除,机械设备也已不存在,厂址荒废,已长出杂草和灌木。
据调查,该电站已于2013年9月开工重建,截至到2014年5月,已经完成了进水口和冲沙闸改造;引水渠道建完1.1km;压力前池、压力管道建设;厂房框架建设等工程内容。
水电站评估资料一、引言水电站评估是对水电站的技术、经济、环境等方面进行全面评估,以确定其运行状况、潜力和可持续发展能力。
本文将介绍水电站评估所需的资料和标准格式。
二、资料要求1. 水电站基本信息:包括水电站名称、所在地、建设单位、投产日期、总装机容量等。
2. 水能资源情况:包括流域面积、平均年径流量、最大年径流量等。
3. 水电站工程设施:包括水库、引水系统、发机电组、变电站等。
4. 发机电组技术参数:包括装机容量、发机电型号、额定水头、额定流量、发机电效率等。
5. 水电站运行数据:包括年发电量、发机电组利用小时数、机组负荷率等。
6. 水电站环境影响评价:包括水库蓄水对周边生态环境的影响、水电站运行对水质、水温的影响等。
7. 水电站经济评价:包括投资回收期、内部收益率、发电成本等。
8. 水电站安全评价:包括水库安全、发机电组运行安全等。
三、标准格式1. 封面:包括水电站名称、评估日期、编制单位等。
2. 目录:列出各章节及页码。
3. 引言:简要介绍水电站评估的目的和重要性。
4. 水电站基本信息:按照要求列出水电站的基本信息。
5. 水能资源情况:介绍水电站所在流域的水能资源情况。
6. 水电站工程设施:详细描述水电站的工程设施情况。
7. 发机电组技术参数:列出水电站发机电组的技术参数。
8. 水电站运行数据:分析水电站的运行数据,评估其运行状况。
9. 水电站环境影响评价:评估水电站对环境的影响,提出相应的改善建议。
10. 水电站经济评价:对水电站的经济效益进行评估和分析。
11. 水电站安全评价:评估水电站的安全状况,提出相应的安全改善措施。
12. 结论:总结水电站评估的结果,提出发展建议。
13. 参考文献:列出评估过程中所参考的文献资料。
14. 附录:包括评估过程中所使用的数据表格、图表等。
四、示例数据1. 水电站基本信息:水电站名称为XX水电站,位于XX省XX市,建设单位为XX公司,投产日期为2005年,总装机容量为100兆瓦。
甘孜州无量河确如多水电站环境影响报告书(公示本)四川省环科院科技咨询有限责任公司2015年7月2目录第一章总则············································································································1-11.1 任务由来及评价工作简况····································································1-11.2 编制目的与评价原则············································································1-21.3 编制依据·······························································································1-41.4 评价标准·······························································································1-91.5 评价工作等级·····················································································1-121.6 评价范围与时段··················································································1-151.7 环境保护目标·····················································································1-171.8 评价工作重点·····················································································1-201.9 评价工作程序·····················································································1-21 第二章工程概况····································································································2-12.1 流域及工程河段规划简况····································································2-12.2 工程地理位置·······················································································2-62.3 工程任务、规模与运行方式································································2-72.4 项目组成及原辅材料··········································································2-142.5 工程总体布置与主要建筑物······························································2-162.6 工程施工布置及进度··········································································2-182.7 建设征地及移民安置··········································································2-44 第三章工程分析····································································································3-13.1 与产业政策和相关规划的符合性分析················································3-13.2 工程设计方案的环保合理性······························································3-143.3 工程施工布置环保合理性··································································3-203.4 工程活动及影响源强分析··································································3-253.5 影响源及部位分析··············································································3-293.6 工程分析结论·····················································································3-31第四章规划阶段与可研阶段方案调整环境可行性论证···································4-14.1 流域水电规划概况················································································4-14.2 设计方案变更过程················································································4-14.3 最终确定的设计方案与规划阶段主要指标的对比分析·····················4-24.4 调节方式改变对下游的影响································································4-44.5 坝址下移及正常蓄水位抬高的环境合理性分析·································4-74.6 环境可行性评价结论··········································································4-17 第五章工程地区环境状况····················································································5-15.1 自然环境·······························································································5-15.2 生物多样性·························································································5-285.3 社会环境·····························································································5-745.4 环境现状评价及主要环境问题··························································5-77 第六章工程建设对环境影响预测·······································································6-16.1 地表水环境影响····················································································6-16.2 地下水环境影响评价··········································································6-366.3 河道演变及河势稳定评价··································································6-416.4 环境空气影响·····················································································6-516.5 声环境的影响预测··············································································6-526.6 固体废物对环境的影响······································································6-556.7 施工公路建设影响··············································································6-566.8 环境地质影响·····················································································6-576.9 水土流失影响·····················································································6-716.10 生态环境及生物多样性影响预测····················································6-756.11 社会环境影响··················································································6-104 第七章环境保护措施及其技术经济论证···························································7-17.1 设计原则及目标····················································································7-17.2 设计内容·······························································································7-17.3 环境保护措施及对策············································································7-47.4 环境保护措施技术经济论证······························································7-76 第八章环境风险分析····························································································8-18.1风险评价因子选择·················································································8-18.2 渣场风险评价·······················································································8-18.3 引水隧洞风险评价················································································8-28.4 油料运输环境风险评价········································································8-38.5 炸药库风险评价····················································································8-48.6 森林火灾风险评价················································································8-58.7 施工期风险事故应急预案····································································8-6 第九章环境监测与管理计划···············································································9-19.1 环境监测计划·······················································································9-19.2 跟踪监测与评价····················································································9-89.3 施工期环境监理····················································································9-99.4 环境管理计划·····················································································9-109.5 环境保护措施及管理实施计划··························································9-12 第十章环境保护投资估算及环境影响经济损益分析·····································10-110.1 环境保护投资····················································································10-110.2 环境影响经济损益分析····································································10-8 第十一章公众参与······························································································11-111.1目的····································································································11-111.2 公众参与的实现················································································11-111.3 结果统计与分析评价········································································11-411.4 公众关心的主要问题及结果处理····················································11-6。
金沙江银江水电站环境影响报告书(简本)建设单位:X X公司编制单位:长江水资源保护科学研究所二○一七年四月目录1 建设项目概况11.1 工程地理位置11.2 工程建设背景11.3 工程概况11.4 与相关规划协调性分析82 建设项目周围环境现状92.1 建设项目所在地环境现状92.2 建设项目环境影响评价范围123 建设项目环境影响预测及拟采取的主要措施14 3.1 环境影响因素及源强分析143.2 环境保护目标163.3 环境影响预测评价183.4 环境保护对策措施243.5 环境风险分析及对策措施293.6 环境管理及监测294 公众参与315 环境影响评价结论316 联系方式321 建设项目概况1.1 工程地理位置银江水电站位于金沙江干流中游末端的攀枝花河段上,是金沙江干流中游水电开发的最后一个梯级。
坝址位于金沙江和雅砻江汇合口上游约3.6km,上距攀枝花市中心城区(攀枝花水文站断面)约10.0km,上游衔接梯级为金沙水电站,两梯级相距21.39km。
工程地理位置见附图1。
1.2 工程建设背景针对攀枝花河段,长江勘测规划设计研究有限责任公司(以下简称长江设计公司)编制完成了《金沙江攀枝花河段水电规划报告》,推荐该河段采用金沙+银江两级开发方案。
2010年,国家发改委下发了《国家发展改革委办公厅关于金沙江攀枝花河段水电规划报告的复函》(发改办能源[2010]1313号),同意金沙江攀枝花河段按金沙和银江两级方案开发。
2009年5月,国家环境保护部以环办函[2009]436号文,下发了《关于金沙江中游河段水电梯级开发环境影响评价及对策研究报告审查意见的函》。
2012年10月,国家发改委办公厅以发改办能源[2012]2950号文同意银江水电站开展前期工作。
受XX公司的委托,长江设计公司承担了银江水电站预可行性研究和可行性研究阶段的勘察设计工作。
1.3 工程概况银江水电站位于金沙江干流中游末端的攀枝花河段上,是金沙江干流中游水电开发的最后一个梯级。
环境影响评价 (其中标红处的主要数字及内容均依工程具体情况而定) 2.6.2 控制生态破坏、生态恢复和防治污染目标 ⑴.控制生态破坏目标 优化施工布置,控制施工占地,减少对工程地区现有土地的占压和破坏,加
强施工管理,优化施工工艺,减轻工程活动对当地动植物造成的不利影响,维护工程及周边区域的生态完整性; ⑵.生态恢复目标 采用工程措施和植物措施相结合的方式达到生态恢复的目的:重视开挖边坡及渣场防护,通过维护弃渣边坡和种植草植被措施,使水土流失总治理度达到80%以上。XXX水电站水土流失防治目标见表9-3。 XXX水电站水土流失防治目标一览表 表9-3
序号 防治指标 建设期 试运行期 1 扰动土地整治率(%) 90 2 水土流失治理度(%) 80 3 土壤流失控制比 ≥1 ≥1 4 拦渣率(%) 85 90 5 林草植被恢复率(%) 90 6 林草覆盖率(%) 15 ⑶.防治污染目标
①.防治水污染目标 要维持项目区河段水体Ⅳ类水域功能标准,污水排放应执行《污水综合排放标准》(GB8978-1996)中污染物允许排放浓度中的二级标准。 ②.防治大气污染目标 采用先进施工手段和一些可行的防扬尘措施(如施工道路洒水降尘等),使施工期扬尘等主要污染物排放达到《大气污染物综合排放标准》(GB16297-1996)新建无组织排放标准要求。 ③.防治噪声污染目标 合理安排施工方式和施工运输时间,降施工区噪声控制在《建筑施工场界噪 声限值》(GB12523-90)标准允许值以下。 ④.防治固体废物污染目标 施工中开挖产生的弃渣应尽量做到回用,渣场要做好防洪河防流失处理。生活垃圾应及时集中收集、分选、清运,运至就近渣场进行卫生填埋处理。工程运行中大坝拦挡的上游漂浮物,应及时打捞清理。 1 环境影响预测与评价
1.1 施工期对环境的影响 1.1.1对地表水质的影响 施工期废污水主要来源于生产废水和生活污水两大部分。生产废水主要为砂砾料的冲洗废水,大坝基础开挖时的基坑排水,混凝土拌合机的冲洗废水。生产废水进入河流后会增加水的浊度和碱度,生活污水主要来源于民工营地,但排放量较少。 (1)混凝土骨料加工系统废水 砂石料冲洗水:平均冲洗10.0m3砂石料产生废水1.20 m3,本工程需用砂石料63738m3,总产生冲洗废水76485.6m3。 混泥土养护碱性水:养护1.0m3混凝土产生碱性废水0.35kg,本工程总混凝土量为37038m3,总产生养护碱性废水12.96t。 砂石料加工系统冲洗用水比较少,主要污染物为悬浮物(ss),其浓度约为5000mg/L,此部分废水具有水量小、浓度高,间隙性集中排放的特点,其浓度远远超过了《污水综合排放标准》(GB8978—1996)的二级标准,需采取简单沉淀处理后排放。 (2)基坑排水 基坑排水分为初期排水和经常性排水两种。废水主要产生于基础开挖中的渗水和降水,基坑废水中悬浮物浓度约为2000mg/l,超过了二级排放标准,需简单沉降处理后排放。 (3)含油废水 工程施工期间汽车、机械等冲洗水含油,若直接排放,在水体表面会形成一层油膜,对水体含氧和河水水质造成一定影响,需设隔离油池进行分化处理后排放。 (4)生活污水 生活污水来源于施工期施工人员的生活废水,按高峰期人数180人、日用水量60L/d人、排放系数0.8计算,污水日排放量为8.6吨,需处理达标后排放或用于绿化用水。
1.1.2 对环境空气的影响(是否需要爆破依工程而定) 工程施工期间大气污染物主要来源于基础及料场的开挖、材料运输堆放、混凝土加工等施工产生的扬尘、地面爆破产生的粉尘及施工机械排放的CO、CO2、氦氧化物的尾气等。 粉尘主要来源于开挖、筛分、转运及拌合等施工过程中,属间歇性,暂时性的无组织非点源排放,由于施工期机械台班少而分散,对施工区周围大气环境质量影响不大。 本工程爆破作业主要是施工临时工程基础岩石的开挖,开挖总方量为605m3,炸药用量0.15吨,爆破工程量不大。其它建筑物基础岩石开挖总方量虽然较大,为5.08万m3,但基础岩性均以泥岩为主,无须采取爆破措施。由于工程区距XXX村和红古村比较近,最近距离仅100m左右,爆破产生的粉尘及co、NOx、c2h2
等有害气体对周围村民有一定影响,但由于爆破污染物属于间歇性排放,而且周
围比较空广,对大气造成的污染不大。 由于工程小施工机械用量不大,其尾气排放量有限,不足于显著影响当地大气环境质量。
1.1.3 对声环境的影响 工程区噪声来源主要有:爆破产生的噪声,施工机械产生的噪声和运输车辆产生的噪声等。由于爆破工程比较少,爆破次数有限,对区域内声环境影响不大。施工机械和运输车辆的噪声对当地村民有一定的影响。因此,在工程施工期间,为减少噪声对两岸居民的生产生活带来的影响,务必要采取措施降低噪声。
1.1.4 对生态环境的影响 工程施工期对陆生生态的破坏主要源于施工占压、开挖、剥离和堆积活动以及施工道路的建设均会使原有的地貌遭到破坏,造成水土流失。XXX水电站工程永久占地共计831.7亩,其中,空闲地115.4亩、水域707.1亩(其中原水域506亩)、果园地9.2亩。工程总临时占地99.15亩,其中占用空闲地70.55亩, 占用果园地28.60亩。 占地多为空闲地和水域,因此工程的剥离、扰动、施工及永久道路的进占不足于影响生态系统的完整性,采取措施后使影响降到最低程度。 由于受施工人群活动影响,施工期间水、气、声环境的改变,地表扰动对动物的栖息环境造成干扰。但项目区附近仅有兔、鼠类动物及麻雀等鸟类,没有国家级保护动物,且附近与施工期区域相似的生存环境易于寻找,受到惊扰的动物可在临近区域重新找到合适的生存环境,工程施工对陆生动物群的组成及数量不会造成影响。
1.1.5 对水土流失的影响 根据工程施工特点,施工期造成的水土流失原因主要有:闸坝、厂房的基础开挖、右岸护堤的基础开挖、施工道路的修建、民工临时营地及生活区的建设、当地材料的开采及运输,弃渣等。在这些项目的活动和项目建设过程中,必将扰动地表,导致地表原状土壤结构和植被的破坏,使保土能力降低,水土保持能力减弱,水土流失增加。
1.1.6 固体废弃物造成的影响 施工期固体废弃物主要包括生产弃渣及生活垃圾。其中生产弃渣主要来自拦河闸坝、厂房及尾水渠、上游库区护堤等的基础开挖,总开挖量为11.26万m3,施工围堰、护堤及枢纽区墙后回填共利用10.85万m3,实际弃渣方量0.41万m3。弃渣沿右岸尾水渠边墙堆放成堤,并可用于右岸进入库区公路的加高等。 电站施工期平均每天上工人数115人,每天每人产生的生活垃圾按0.50kg计算,则每天生活垃圾的排放量为0.06t,工期按两年计算,总排放量为43.8t。生活垃圾应集中堆放,并定期拉运至XXX垃圾场进行无公害卫生填埋处理,杜绝病菌滋生渠道,保护人群健康。
1.1.7对社会环境的影响 XXX水电站属Ⅳ等小㈠型工程,工程建设中所需物资和劳力和今后的运行管理将推动当地工业的发展和增加就业渠道,工程施工中需技普工总劳力180376工日,可动用当地剩余劳动力,刺激当地经济的发展,增加群众收入,提高居民生活水平。 施工人员消费需求的增加,将促进当地农业,餐饮业和其他服务行业的发展, 对当地农业产业结构的调整及第三产业的发展产生影响。 工程建设期间本地及外来施工人员较多且相对集中,高峰施工人员数高达180人,居住及卫生条件较差,再加劳动强度较大,人员免疫力相对较低,发生各种疾病和感染的可能性较大,对当地居民及施工人员本身会产生不利影响。
1.1.8其他影响 项目建成后,由于河流水位的抬高,淹没XXX村抽水泵房一座。泵房位于引水渠组上游70m处,主要用于农灌及林灌,本阶段考虑在工程开工前对该泵房予以搬迁补偿。
1.2 运行期水环境影响预测 1.2.1 对水文情势的影响 水库蓄水后,水面面积加大,水深明显增加,库内水流流速明显减缓,由急流变成缓流。由于电站为河床式,按照自然流量发电因此坝后水流的时空分布不会改变。
1.2.2 对水质的影响 根据工程河段污染源现状调查,本工程河段执行《地表水环境质量标准》(GB3838-2002)Ⅳ类水域标准。结合区域内没有污染性企业,近期也不会发展大规模的污染性企业,因此近期内污染源不会发生明显变化。 为防止蓄水对水库水质产生影响,在水库蓄水前,将对淹没区进行库底清理,因此不存在大量植物在库内腐烂而导致水质恶化的可能。水库运行初期,由于淹没土壤中含有的部分富营养物质及少量库内枯枝落叶等有机物会对水质有一定的影响。
1.2.3 对地质环境的影响 XXX电站的水库为谷盆式水库,水库库容不大。湟水河民和站实测多年平均含沙量10.6Kg/m3,泥沙含量很大,根据水文分析成果,坝址断面多年平均悬移输沙量为1958万吨,推移质输送490万吨,年输沙总量2448万吨。工程虽有冲沙设施,但淤积年限很短。 库区两岸为湟水河Ⅰ、Ⅱ及阶地,除库右岸的前段和库左岸的后段自然地形较陡处,其余地段地形比较平缓。高陡的地段由于为白垩系的泥岩地层,在库水 的长期侵蚀下会产生少量的坍岸,但规模不大,形成坍岸的时间较长。对水库运行不会有大的影响。 水库蓄水后,由于水位的升高库区附近的地下水位会有小幅抬升,但由于两岸沙砾石地层出露高程较高,毛细管上升作用不明显,因此浸没影响比较小。为了防止浸没的影响,拟在水库的后段的右岸,做混凝土防渗墙围护,防渗墙顶高于正常蓄水位,防渗墙底嵌入不透水的泥岩地层内,并且墙后设直径为0.40m的排水管排水,以防止库水对右岸局段农地的浸没影响。
1.2.4 对生态环境的影响 ⑴ 对局地气候的影响 水库表面积46.25km2,由于水面面积的增加,蒸发量加大,库区周围将形成湿度较高的中心,湿度随离库岸距离的增加而减少。据经验分析,一般年平均湿度增加2%,冬春增加幅较小,夏秋增加幅度较大。水库建成后,库区周围温度会略有改变,年气温约增加0.15c,冬季气温略有增加,而夏季气温略有减少。气温和湿度的增加有利于库区周边喜温室植物的生长,但湿度、温度的轻微变化不会改变降水因子。 ⑵ 对生物的影响 工程区位于青海省东部农业区内,植被较发育,电站运行后,由于库水位低,对两岸农田和果园影响较小,对渗漏较大的库区右岸修建防护堤工程,也起到大大减少库区淹没及浸没范围,因此电站运行后对周围植被资源的影响较轻微。 ⑶ 对景观生态体系稳定性的影响 该工程对景观生态体系稳定性的影响主要集中在工程建设区、水库影响区。水库蓄水后,淹没区原有生态体系变为水域,对区内景观异质性无实质影响。 就整个平价区域而言,工程施工、水库淹没对景观生态体系的质量没有重大影响,在采取植被恢复、水土流失防治等生态保护措施后,生态影响可有效减少,景观生态体系的稳定性仍将保持现有水平。
