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A Capacitive Pressure Sensor With Adjustable Working Range for Deep Sea

Abstract

Pressure sensors have widespread applications across various fields in air and underwater environments. However, the drastic pressure difference makes it hard for pressure sensors to measure air and deep-sea pressure under the same mechanism. In this study, we present a design of a capacitive pressure sensor based on the soft sensing membrane bending deformation to measure air pressure or extreme hydrostatic pressure. A mechanical model was developed to analyze the relationship between the membrane capacitance and the external pressure condition on different compressible mediums of the sensor. By changing the compressible mediums, the deformability of the sensor membrane under load can be modulated, enabling rapid adjustments to the working range of the sensor by at least four to five orders of magnitude. In the experiments, the sensor demonstrated the capability to monitor gas pressures of 1 kPa in air and hydrostatic pressures of 100 MPa (equal to hydrostatic pressure at a depth of 10000 m) in the pressure vessel. With consistent and stable performance across a low-to-high measurement range, this sensor proves versatile for applications such as wind pressure, depth, and environmental pressure measurements.

article Article

date_range 2024

language English

link Link of the paper

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Wang Haijun

Ruan Dongrui

Gan Letian

Shen Zihang

Zhuo Jiangshan

Chen Xiangping

Zhou Fanghao

Jia Zheng

Li Tiefeng

Hu Huizhu

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Featured Keywords

Sensors

Sensor phenomena and characterization

Pressure sensors

Deformation

Pressure measurement

Robot sensing systems

Capacitive sensors

Adjustable working range

capacitive sensing

deep-sea pressure

electromechanical modeling

pressure sensor

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Assessment of reinforced concrete building damages following the Kahramanmaraş earthquakes in Malatya, Turkey (February 6, 2023)

Abstract

Earthquakes of magnitude Mw = 7.7 and Mw = 7.6 hit the city of Kahramanmaraş (Turkey) on 6 February 2023. These earthquakes caused serious damage in 11 provinces in Turkey resulting in over 50,000 deaths and huge economic losses with the collapse of thousands of buildings. Two consecutive devastating earthquakes have severely damaged the reinforced concrete building stock located in Malatya. There are many reasons reinforced concrete structures suffer damage under the influence of seismic loads. These reasons can be listed as material and section properties that do not comply with earthquake codes, workmanship defects, ground parameters that are not considered and design errors, as seen in field investigations after earthquakes in Turkey in the past. In this research, a field study was conducted on reinforced concrete buildings damaged after the earthquakes in Malatya province. The causes of structural damages in reinforced concrete buildings between 6–26 years of age were assessed in terms of design and material defects. The structural damages were mainly caused due to insufficient stirrups in structural members, short column, strong beam–weak column, failures of infill walls, soft story type collapse, poor concrete quality, and reinforcement corrosion. In addition to the field investigation, the spectrum relationships created using raw acceleration data obtained from DEMP (Disaster and Emergency Management Presidency) stations in Malatya province were compared with the design response spectra.

article Article

date_range 2024

language English

link Link of the paper

Collapsed buildings

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