甘肃省地下水观测资料效能评估结果分析
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摘要
对甘肃省19个水位测项、3个流量测点、13个水温测点(18个测项)的观测资料,从观测资料质量、基础资料、震例应用等方面来进行总体分析评估(90分以上、A级:80分以上B级:60分以上C:60分以下D级)。水位(流量)评估结果为A级4个测点,B级6个测点,C级8个测点。另外2个测点由于资料报送不及时未评估,1个测点仪器故障停测。水温评估结果为A级1个测项,B级10个测项,C级6个测项,D级1个测项。
This paper collected fluid data in Gansu province,including 19 water level items,3 flow-rate measuring points and 13 water temperature points(namely 18 items),and then analyzed and evaluated the data in aspects of observed data quality,basic data information and the earthquake application(Class A: over 90 points;Class B: over 80 points;Class C∶over 60 points;Class D: lower than 60 points).The result of water level evaluation is classified to 3 ranks(class A∶ 4 measuring points involved,class B∶ 6 measuring points involved,class C∶ 8 measuring points involved),the other 2 points is not evaluated due to the delayed data and also there is 1 point is stopped measuring on account of instrumental fault.Water temperature result is as follows:1 class A,10 class B,5 class C,2 class D.
This paper collected fluid data in Gansu province,including 19 water level items,3 flow-rate measuring points and 13 water temperature points(namely 18 items),and then analyzed and evaluated the data in aspects of observed data quality,basic data information and the earthquake application(Class A: over 90 points;Class B: over 80 points;Class C∶over 60 points;Class D: lower than 60 points).The result of water level evaluation is classified to 3 ranks(class A∶ 4 measuring points involved,class B∶ 6 measuring points involved,class C∶ 8 measuring points involved),the other 2 points is not evaluated due to the delayed data and also there is 1 point is stopped measuring on account of instrumental fault.Water temperature result is as follows:1 class A,10 class B,5 class C,2 class D.
引文
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[2]耿杰,陈安方,潘双进.无线地下流体数据监测系统水位观测数据与模拟水位观测数据一致性研究[J].地震研究,2008,31(3):238-243.
[3]汪成民,车用太,万迪坤,等.地下水微动态研究[M].北京:地震出版社,1988.
[4]王吉易,董守玉,陈建民,等.地下流体地震预报方法[M].北京:地震出版社,1997.
[5]车用太,孔令昌,陈华静,等.地下流体数字化观测技术[M].北京:地震出版社,2002.
[6]张立,赵洪声,刘耀炜,等.云南会泽井水位与水温相关关系及其变异的地震预测意义[J].地震研究,2009,32(3):228-230.
[7]许秋龙,王道,地下流体数字化观测条件和技术研究[J].内陆地震,2001,15(1):39-48.
[8]安镇文,朱传镇.地热异常与地震孕育和发生的关系[J].地震研究,1985,8(4):541-548.
[9]张之立,田华.山西大同震群序列的震源力学特征和有限元数值模拟[J].地震学报,1995,17(1):11-19.
[10]谷元珠,车用太,鱼金子,等.塔院井水温微动太研究[J].地震,2003,23(1):102-108.
[11]赵文忠,车用太,刘成龙,等.京津冀地区井水温度的数字化观测及其地震前兆监测效能的评估[J].地震,2006,26(4):121-128.
[12]张昱,钟美娇,杨晓鹏,等.平凉C11井地下流体数字化水位观测资料的分析[J].地震,2008,28(4):128-135.
[13]张昱,刘小凤,邵辉成,等.甘肃“十五”数字化水位观测资料分析及地震前兆监测效能评估[J].地震研究,2010,33(4):281-287.
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