Pressure Transducer Measurement Variability in Deep Wells Screened Across the Water Table.

IF 2 4区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Groundwater Pub Date : 2024-09-18 DOI:10.1111/gwat.13441

John P McDonald

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Abstract

Automated water level measurements collected using vented pressure transducers in deep wells screened across the water table may exhibit a greater response to barometric pressure changes than the true water level. The cause was hypothesized to be disequilibrium in barometric pressure between the wellbores and land surface due to air exchange with the deep vadose zone. In this study, vented and nonvented pressure transducers were installed and operated simultaneously in two deep wells screened across the water table. A vent tube open to the atmosphere at land surface allowed for barometric compensation of the vented transducers. Two nonvented transducers were installed in each well, one submerged in the water and one above the water surface. The difference in readings allowed for barometric compensation. Manual measurements were also collected. It was confirmed that measurements from the vented transducers exhibited greater variability in response to barometric pressure changes than the nonvented transducers and manual measurements. Comparison of the downhole barometric pressure measurements to values from a nearby meteorology station showed the response in the wells to changes in barometric pressure was time-lagged and attenuated. Thus, the reference pressure from land surface supplied to the vented transducers was not representative of the air pressure within the wells. This caused fluctuations of the transducer readings in response to barometric pressure changes to be greater than the true water level change. This issue can be resolved by the use of nonvented pressure transducers.

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跨水位筛选深井中的压力传感器测量变异性。

在横跨地下水位的深井中，使用排气压力传感器收集的自动水位测量值对气压变化的反应可能大于真实水位。据推测，其原因是井筒和地表之间的气压不平衡，这是因为与深层岩溶带进行了空气交换。在这项研究中，在两口横跨地下水位的深井中同时安装并运行了通气和不通气压力传感器。地面上有一个通向大气的排气管，可对排气式传感器进行气压补偿。每口井都安装了两个无通气传感器，一个浸没在水中，另一个位于水面之上。读数的差异可用于气压补偿。还收集了人工测量数据。经证实，与不通风的传感器和人工测量相比，通风传感器的测量值对气压变化的响应变化更大。将井下气压测量值与附近气象站的气压测量值进行比较后发现，气压井对气压变化的响应具有时滞性和衰减性。因此，提供给排气传感器的地面参考气压并不能代表井内的气压。这导致传感器读数随气压变化而产生的波动大于真实的水位变化。这个问题可以通过使用无通气压力传感器来解决。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Groundwater 环境科学-地球科学综合

CiteScore

4.80

自引率

3.80%

发文量

审稿时长

12-24 weeks

期刊介绍： Ground Water is the leading international journal focused exclusively on ground water. Since 1963, Ground Water has published a dynamic mix of papers on topics related to ground water including ground water flow and well hydraulics, hydrogeochemistry and contaminant hydrogeology, application of geophysics, groundwater management and policy, and history of ground water hydrology. This is the journal you can count on to bring you the practical applications in ground water hydrology.