Pattern Recognition Approach to Fault Diagnosis in the DAMADICS Benchmark Flow Control Valve

Abstract There are the problems in the traditional pressure-compensation flow-control valve, such as low flow control accuracy, small flow control difficulty, and limited flow range. For this, a method of continuous control pressure drop Δprated (i.e. the pressure drop across the main throttling orifice) to control flow-control valve flow is proposed. The precise control of small flow is realized by reducing the pressure drop Δprated and the flow range is amplified by increasing pressure drop Δprated. At the same time, it can also compensate the flow force to improve the flow control accuracy by regulating the pressure drop Δprated. In the research, the flow-control valve with controllable pressure compensation capability (FVCP) was designed firstly and theoretically analyzed. Then the sub-model model of PPRV and the joint simulation model of the FVCP were established and verified through experiments. Finally, the continuous control characteristics of pressure drop Δprated, the flow characteristics, and flow force compensation were studied. The research results demonstrate that, compared with the traditional flow-control valve, the designed FVCP can adjust the compensation pressure difference in the range of 0∼3.4 MPa in real-time. And the flow rate can be altered within the range of 44%∼136% of the rated flow. By adjusting the compensation pressure difference to compensate the flow force, the flow control accuracy of the multi-way valve is improved, and the flow force compensation effect is obvious.

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CFD Simulations and Tests of a Prototype Flow Control Valve

Lecture Notes in Mechanical Engineering - Advances in Hydraulic and Pneumatic Drives and Control 2020 ◽

10.1007/978-3-030-59509-8_11 ◽

2020 ◽

pp. 123-134

Author(s):

Marta Zaleska-Patrosz ◽

Piotr Patrosz ◽

Paweł Śliwiński

Keyword(s):

Flow Control ◽

Control Valve ◽

Flow Control Valve ◽

Cfd Simulations

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Vertical Vibration Suppression of a Railway Vehicle by Damping Control of an Air Spring with Flow Control Valve

TRANSACTIONS OF THE JAPAN FLUID POWER SYSTEM SOCIETY ◽

10.5739/jfps.43.93 ◽

2012 ◽

Vol 43 (4) ◽

pp. 93-101

Author(s):

Akihito KAZATO ◽

Yoshiki SUGAHARA ◽

Reiko KOGANEI ◽

Kazushi SANADA

Keyword(s):

Flow Control ◽

Vibration Suppression ◽

Control Valve ◽

Vertical Vibration ◽

Railway Vehicle ◽

Flow Control Valve ◽

Air Spring ◽

Damping Control

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Investigation of thermal mechanical coupling numerical simulation and theoretical study of k-shaped combined metal seal of downhole flow control valve

Thermal Science ◽

10.2298/tsci2104053z ◽

2021 ◽

Vol 25 (4 Part B) ◽

pp. 3053-3061

Author(s):

Linfeng Zhang ◽

Dongsheng He ◽

Ya Tan ◽

Liangbin Xu

Keyword(s):

Flow Control ◽

Contact Stress ◽

Base Alloy ◽

Thermal Structure ◽

Control Valve ◽

Flow Control Valve ◽

Beam Model ◽

Mechanical Coupling ◽

Metal Seal ◽

Seal Assembly

The K-shaped seal assembly is composed of K-shaped metal seal, high temperature nickel base alloy (GH4169). Its sealing performance directly affects the reliability and stability of flow control system. The 2-D axisymmetric K-shaped metal seal is abstracted as the combination of interference fit model and cantilever beam model. Considering the influence of temperature on the seal, based on the 2-D constitutive relation of elastic medium and heat conduction theory, the theoretical model between contact stress and self variation of K-shaped metal seal ring is deduced by using inverse method. Using ABAQUS thermal structure coupling analysis method, the thermal mechanical coupling finite element model of K-shaped seal assembly is established. The theoretical analytical solution proposed in this paper can be used to calculate the approximate solution of contact stress of radial metal seal under current oilfield conditions, and provides theoretical support for the numerical calculation of thermal stress of radial metal seal.

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Design and Fabrication of Two Step Speed Control of a Cylinder Circuit using Pneumatics

International Journal of Engineering and Advanced Technology - Regular Issue ◽

10.35940/ijeat.f1149.0886s219 ◽

2019 ◽

Vol 8 (6S2) ◽

pp. 512-516

Keyword(s):

Flow Control ◽

High Speed ◽

Air Flow ◽

Control Valve ◽

Speed Control ◽

Flow Control Valve ◽

Push Button ◽

Low Speed ◽

Flow Through

The main aim of our project is to design and fabrication of pneumatic two step speed control of a cylinder. Initially the flow from the FRL retracts the cylinder when the push button is in its spring offset position. When it is pushed the flow pilots actuate. The air passes through the flow control and shuttle valve. Then the cylinder extends with high speed as the valve allows more air to enter the cylinder. When the piston reaches the position it operates the cam push button and pilot air flow through this and actuate 5/2 pilot operated valve and reaches flow control valve which permits less air. Then the flow through enters the shuttle valve to cylinder and allows the cylinder to extend at relatively low speed. At the end of extension stroke deactivating push button retracts the cylinder. Thus the speed of cylinder is controlled and project can be achieved

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Calculation of hydraulic resistance in the separator of the direct-flow control valve with a rotary lock

E3S Web of Conferences ◽

10.1051/e3sconf/202022001073 ◽

2020 ◽

Vol 220 ◽

pp. 01073

Author(s):

Anna Kapranova ◽

Anton Lebedev ◽

Alexander Melzer

Keyword(s):

Flow Control ◽

Hydraulic Resistance ◽

Control Valve ◽

Resistance Coefficient ◽

Hydrodynamic Cavitation ◽

Qualitative Assessment ◽

Design Parameters ◽

Flow Control Valve ◽

Direct Flow ◽

Method Of Calculation

The purpose of this work is to analyze the coefficient of hydraulic resistance in the separator of a direct-flow control valve with a rotary lock according to the approximation of the superposition of pressure losses in elementary local resistances. In contrast to the known methods of constructing simulation models, the proposed analytical method of calculation is based on a qualitative assessment of the specified coefficient in the implementation of throttling of fluid flows in the “separator-rotary lock” unit, depending on the design and operating parameters of the process. It was found that, within the selected range of variation of the separator parameters, an increase in the valve opening degree from 20% to 50% leads to a decrease in the hydraulic resistance coefficient by 19.6 times, and an increase in this degree from 20% to 100% is associated with a 42.4-fold decrease in the studied characteristic. This circumstance justifies the effectiveness of the proposed method for throttling the flows of the working medium. The results obtained are used to study the influence of the main design parameters of the “separator-butterfly valve” unit on the flow capacity of the control valve and are relevant for stochastic modeling of the hydrodynamic cavitation process.

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Analysis and testing of a THUNDER piezoelectric actuator as a prime mover in a gas flow control valve

10.1117/12.599624 ◽

2005 ◽

Author(s):

Jesse C. Rodgers ◽

William W. Clark ◽

Jeffrey S. Vipperman

Keyword(s):

Flow Control ◽

Piezoelectric Actuator ◽

Gas Flow ◽

Control Valve ◽

Flow Control Valve ◽

Prime Mover

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The Stiffness and Static Stability of Compensated Hydrostatic Cylindrical-Pad Bearings

Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science ◽

10.1243/pime_proc_1984_198_119_02 ◽

1984 ◽

Vol 198 (4) ◽

pp. 285-292 ◽

Cited By ~ 1

Author(s):

G K Lewis

Keyword(s):

Flow Control ◽

Control Valve ◽

Static Stability ◽

Fluid Film ◽

Flow Control Valve ◽

Static Instability ◽

Film Stiffness

The effect of capillary, orifice and flow-control valve compensation on the fluid film stiffness, ψ, and static instability (ψ = 0) of hydrostatic cylindrical-pad bearings has been examined both theoretically and experimentally. Equations derived from the basic bearing parameters allow the stiffness to be expressed in non-dimensional form and calculated at any load and eccentricity. The equations show that for the same load and eccentricity ψv> ψo> ψc>. For both orifice and capillary compensation the stiffness may reduce to zero and the shaft become unstable as the load and eccentricity are increased. This does not occur with flow-control valve compensation. Here the stiffness increases rapidly with eccentricity. For this type of compensation a greater stiffness is obtained with a smaller port. For a given orifice or capillary the port size determines the eccentricity when instability occurs. To obtain a maximum stable working range and also to increase the stiffness at any eccentricity a large port is preferred with these types of compensation. The size of the compensating element also affects the inception of instability. Maximum allowable values for various port sizes are derived for square ports.

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