[1]陈铖,赵素丽,石秉忠.可压缩流体密度测试系统的设计与应用[J].石油管材与仪器,2018,4(05):5-7.[doi:10.19459/j.cnki.61-1500/te.2018.05.002]
            CHEN Cheng,ZHAO Suli,SHI Bingzhong.Design and Application of Density Measure System for Compressible Fluids[J].Petroleum Tubular Goods & Instruments,2018,4(05):5-7.[doi:10.19459/j.cnki.61-1500/te.2018.05.002]
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            可压缩流体密度测试系统的设计与应用
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            石油管材与仪器[ISSN:2096-0077/CN:61-1500/TE]

            卷:
            4
            期数:
            2018年05期
            ?#38472;?
            5-7
            栏目:
            开发设计
            出版日期:
            2018-10-20

            文章信息/Info

            Title:
            Design and Application of Density Measure System for Compressible Fluids
            文章编号:
            2096-0077201805-0005-03
            作者:
            陈铖 赵素丽 石秉忠
            中国石油化工股份有限公司石油工程技术研究院 ?#26412;?100101
            Author(s):
            CHEN Cheng ZHAO Suli SHI Bingzhong
            Sinopec Research Institute of Petroleum Engineering, Beijing 100101, China
            关键词:
            低密度流体高温高压密度测试
            Keywords:
            low density fluid high temperature and high pressure density test
            分类号:
            P631.4+3
            DOI:
            10.19459/j.cnki.61-1500/te.2018.05.002
            文献标志码:
            A
            摘要:
            低密度流体在石油工程中应用广泛但实际作业中低密度流体在高温高压条件下具有可压缩性导致密度的变化目前流体密度测试多在常温常压中进行不能反映流体在高温高压条件下的真实密度变化因此开发了一种可压缩流体密度评价设备其原理是利用公式=m/V固定试样的质量通过测试体积的变化量计算出密度的变化操作安全方便测试精度高测试范围温度0150 棬压力060 MPa可准确测试泡沫钻井液等低密度流体的密度变化情况
            Abstract:
            The low density fluid is widely used in petroleum engineering. And the low density fluid can be compressed under high temperature and high pressure, which result in the change of the density. At present, the fluid density test is carried out at room temperature and atmospheric pressure, which can not reflect the true density of the fluid under the condition of high temperature and high pressure. Therefore a compressible fluid density evaluation equipment is developed, its principle adopts the formula of =m/V to fix the specimen mass, and then to change the test volume to calculate the density change. The operation is safe and convenient with high test precision; the test parameter range covers the pressure 0-60 MPa and the temperature 0-150 , the density changes of foam drilling low density liquid fluid can be tested accurately.

            参考文献/References:

            [1] 秦积舜,孟红霞.泡沫钻井液密度-压力-温度关系测定[J]. 石油钻探技术,2001,29(6):42-44.
            [2] 叶艳,鄢捷年.高强度空心玻璃微珠低密度水基钻井液室内研究及应用[J]. 石油钻探技术,2006, 34(5):41-44.
            [3] ?#20013;?#26126;,冯学荣,杨?#35745;?等.中空玻璃微珠低密度钻井液的现场应用工艺[J]. 钻井液与完井液2007 24(7):98-100132.
            [4] 程玉华,张鑫,石张泽等.泡沫钻井液实验研究及现场应用[J]. 中国石油和化工标准与质量,2014,38(5):187-188.

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            备注/Memo

            备注/Memo:
            第一作者简介陈铖女1984年生工程师2010年毕业于?#26412;?#21270;工大学高分子化学与物理专业目前主要从事钻井液油田化学方向的研究工作E-mail:[email protected]
            更新日期/Last Update: 2018-10-25
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