Effect of the Dynamic Response of a Side-Wall Pressure Measurement System on Determining the Pressure Step Signal in a Shock Tube Using a Time-of-Flight Method

Svete, A.; Castro, Francisco Javier Hernández; Kutin, J.

doi:10.3390/s22062103

Cited by 17 publications

(7 citation statements)

References 37 publications

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“…A diaphragmless shock tube, which was developed in the Laboratory of Measurements in Process Engineering at the Faculty of Mechanical Engineering in Ljubljana, consists of two straight gas-filled tubes with the same circular cross-section that are initially separated with the fast-opening valve (FOV): a high pressure driver section and a lower pressure driven section, see Figure 1 [2]- [4]. An instantaneous opening of the FOV generates a shock wave that propagates through the driven gas.…”

Section: Diaphragmless Shock Tubementioning

confidence: 99%

“…where 𝑡 last and 𝑥 last are the passage time of the shock wave over the last side-wall pressure sensor installed downstream of the driven section and its location, respectively, 𝑥 wall is the location of the end-wall of the driven section and 𝑉(𝑥) is shock wave velocity distribution along the driven section determined using a time-of-flight (TOF) method [2]- [4].…”

Section: Diaphragmless Shock Tubementioning

confidence: 99%

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Dynamic Calibration of Pressure Sensors With the Use of Different Gases in the Shock Tube

Planko¹,

Svete²,

Kutin³

2023

Proceedings of the 6th IMEKO TC16 Conference on Pressure and Vacuum Measurement

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This paper studies the possibilities of increasing the amplitude range of the generated pressure steps in the developed diaphragmless shock tube by using appropriate combination of gases in the driver and driven sections of the shock tube. The measurement results of the generated pressure steps using different combinations of lower-and highermolecular-weight gases as driver and driven gas are presented. By comparison of the resulting pressure steps generated in the diaphragmless shock tube, the most appropriate combination of the driver and driven gas for generating the largest pressure step amplitudes is determined and discussed.

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Section: Diaphragmless Shock Tubementioning

confidence: 99%

Section: Diaphragmless Shock Tubementioning

confidence: 99%

Dynamic Calibration of Pressure Sensors With the Use of Different Gases in the Shock Tube

Planko¹,

Svete²,

Kutin³

2023

Proceedings of the 6th IMEKO TC16 Conference on Pressure and Vacuum Measurement

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“…The dynamic response of the side-wall pressure measurement system (PMS) used for determining the shock wave passages depends on its frequency response function (FRF), the velocity of the shock wave at the locations of the side-wall pressure sensors Vi and the effective diameter of the side-wall pressure sensors D. In the recent work [6], we have developed the physical mathematical model that simulates the side-wall PMS input and output signals. The developed model considers the integral effect of the shock wave pressure on the pressure sensor to be proportional to the size of the pressure sensor diaphragm's effective area covered by the shock wave and determines the response of the PMS to the input pressure by considering the FRF of the complete side-wall PMS chain.…”

Section: Problem Backgroundmentioning

confidence: 99%

“…The developed model considers the integral effect of the shock wave pressure on the pressure sensor to be proportional to the size of the pressure sensor diaphragm's effective area covered by the shock wave and determines the response of the PMS to the input pressure by considering the FRF of the complete side-wall PMS chain. The use of the physical model requires the information about Vi and D. The effective diameter of four identical sidewall pressure sensors installed along the developed diaphragmless shock tube was determined based on the best fit between the normalised measured output signals of the side-wall PMS and the theoretical output signals obtained with the physical model [6].…”

Section: Problem Backgroundmentioning

confidence: 99%

Method for Correction of the Systematic Errors in Detected Shock Wave Passage Times in the Shock Tube

Castro¹,

Svete²,

Kutin³

2023

Proceedings of the 6th IMEKO TC16 Conference on Pressure and Vacuum Measurement

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The most important uncertainty component of the pressure step signal determined at the end-wall of the shock tube is associated with the uncertainties of the shock wave velocity and the arrival time of the shock front. Both are determined using a timeof-flight method and are therefore greatly affected by the errors in the detected times of the shock wave passages over the side-wall pressure sensors installed along the shock tube. This paper introduces a method for an automated correction of the systematic errors due to non-ideal dynamic response of the side-wall pressure sensors.

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“…On the other hand, in other application areas, such as military engineering, chemical explosion tests [ 4 ], petroleum exploration and well testing [ 5 ], gas turbine testing and combustion engine testing [ 6 , 7 ], and biomedical applications [ 8 ], among others, dynamic calibration of pressure sensors is essential. A typical example that can be referred to in the automotive area is related to air flow control in combustion engines [ 9 ]. Pollution of the combustion air can result in a reduction in the oxygen available for combustion and can alter the chemistry of exhaust emissions, with a negative impact on environmental air quality.…”

Section: Introductionmentioning

confidence: 99%

Pressure Sensors: Working Principles of Static and Dynamic Calibration

Pereira

2024

Sensors

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This paper starts with an overview of the main principles used for pressure measurements, focusing on their usage in industrial applications’ domains. Then, the importance of calibration procedures, namely, static and dynamic calibration of pressure sensors, is analyzed. Regarding calibration, it is important to note that there are several applications where the pressure signals to be measured can have large variations in short periods of time. In industrial applications, particularly in continuous production processes, generally, dynamic pressure measurements are less common; however, they are still required in several cases, such as control loops that are very sensitive to pressure variations, even if the frequencies of those variations are in the range of a few tens of hertz, or even lower. The last part of the paper presents the hardware and software of a flexible and low-cost static and dynamic pressure calibrator that also presents the capability to generate arbitrary waveform pressure signals for calibration and testing purposes. The proposed calibrator also includes the following advantages: remote pressure sensing capabilities that can be used to minimize calibration errors, such as those associated with capillary effects and pressure leakages; portability; and low cost. The paper ends with some experimental results obtained with the proposed calibrator.

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Effect of the Dynamic Response of a Side-Wall Pressure Measurement System on Determining the Pressure Step Signal in a Shock Tube Using a Time-of-Flight Method

Cited by 17 publications

References 37 publications

Dynamic Calibration of Pressure Sensors With the Use of Different Gases in the Shock Tube

Dynamic Calibration of Pressure Sensors With the Use of Different Gases in the Shock Tube

Method for Correction of the Systematic Errors in Detected Shock Wave Passage Times in the Shock Tube

Pressure Sensors: Working Principles of Static and Dynamic Calibration

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