Hydrostatic Testing of Control Valves
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Chapter 7 Control Valves
INTRODUCTION
In process systems, the final control element is normally a pneumatically actuated control valve, which is used to pneumatically actuated control valve, which is used to regulate the flow of a fluid. It provides the necessary power to translate the controller to translate the controller s' output to the process output to the process. Pneumatics is used because of the original popularity of
pneumatic control systems and the comparatively low pneumatic control systems and the comparatively low operating pressures used, also for safe operation in the hazards facilities hazards facilities.
As shown in the figure, in the basic components of a control loop, the control valve is subject to the harshest conditions.
A control valve is also the most expensive item and the most prone to incorrect selection.
Chapter 7 Control Valves
INTRODUCTION
In process systems, the final control element is normally a pneumatically actuated control valve, which is used to pneumatically actuated control valve, which is used to regulate the flow of a fluid. It provides the necessary power to translate the controller to translate the controller s' output to the process output to the process. Pneumatics is used because of the original popularity of
pneumatic control systems and the comparatively low pneumatic control systems and the comparatively low operating pressures used, also for safe operation in the hazards facilities hazards facilities.
As shown in the figure, in the basic components of a control loop, the control valve is subject to the harshest conditions.
A control valve is also the most expensive item and the most prone to incorrect selection.
Cavitation in Control Valves
Introduction
Cavitation has been a familiar phenomenon for a long time particularly in shipping. In 1917, the British physicist Lord Rayleigh was asked to investigate what caused fast-rotating ship propellers to erode so quickly. He discovered that the effect of cavitation, already proved in experiments by Reynolds in 1894, was the source of the problem. Despite numerous investigations into the subject of cavitation in the years that followed, many of the accompanying effects have still not yet been completely explained. This is no wonder considering the complexity of the process involving the areas of acoustics, hydrodynamics, thermodynamics, optics, plasma physics and chemistry.
Cavitation can be caused in a fluid by energy input. For example, a laser beam creates a plasma in liquids which causes the liquid to evaporate creating a cavity. Ultrasonic waves can be used to induce complex high-frequency alternating compression and rarefaction phases in liquids which cause cavitation. In this way, cavitation effects can be applied usefully for cleaning surfaces, for non-invasive operations in the field of medicine and for breaking down agglomerates in the textile finishing industry. In sewage treatment plants, cavitation is used to break down molecules and bacteria cell walls, break up pollutants and dissolve out minerals from organic material
Furthermore, cavitation can arise in hydrodynamic flows when the pressure drops. This effect is, however, regarded to be a destructive phenomenon for the most part. In addition to pump rotors, control valves are particularly exposed to this problem since the static pressure at the vena contracta even at moderate operating conditions can reach levels sufficient for cavitation to start occurring in liquids.
Cavitation in Control Valves
Introduction
Cavitation has been a familiar phenomenon for a long time particularly in shipping. In 1917, the British physicist Lord Rayleigh was asked to investigate what caused fast-rotating ship propellers to erode so quickly. He discovered that the effect of cavitation, already proved in experiments by Reynolds in 1894, was the source of the problem. Despite numerous investigations into the subject of cavitation in the years that followed, many of the accompanying effects have still not yet been completely explained. This is no wonder considering the complexity of the process involving the areas of acoustics, hydrodynamics, thermodynamics, optics, plasma physics and chemistry.
Cavitation can be caused in a fluid by energy input. For example, a laser beam creates a plasma in liquids which causes the liquid to evaporate creating a cavity. Ultrasonic waves can be used to induce complex high-frequency alternating compression and rarefaction phases in liquids which cause cavitation. In this way, cavitation effects can be applied usefully for cleaning surfaces, for non-invasive operations in the field of medicine and for breaking down agglomerates in the textile finishing industry. In sewage treatment plants, cavitation is used to break down molecules and bacteria cell walls, break up pollutants and dissolve out minerals from organic material
Furthermore, cavitation can arise in hydrodynamic flows when the pressure drops. This effect is, however, regarded to be a destructive phenomenon for the most part. In addition to pump rotors, control valves are particularly exposed to this problem since the static pressure at the vena contracta even at moderate operating conditions can reach levels sufficient for cavitation to start occurring in liquids.
Liquid Process Piping Part 5: Valves
For liquid piping systems, valves are the controlling element. Valves are used to isolate equipment and piping systems, regulate flow, prevent backflow, and regulate and relieve pressure. The most suitable valve must be carefully selected for the piping system. The minimum design or selection parameters for the valve most suitable for an application are the following: size, material of construction, pressure and temperature ratings, and end connections. In addition, if the valve is to be used for control purposes, additional parameters must be defined. These parameters include: method of operation, maximum and minimum flow capacity requirement, pressure drop during normal flowing conditions, pressure drop at shutoff, and maximum and minimum inlet pressure at the valve. These parameters are met by selecting body styles, material of construction, seats, packing, end connections, operators and supports.
Liquid Process Piping Part 5: Valves
For liquid piping systems, valves are the controlling element. Valves are used to isolate equipment and piping systems, regulate flow, prevent backflow, and regulate and relieve pressure. The most suitable valve must be carefully selected for the piping system. The minimum design or selection parameters for the valve most suitable for an application are the following: size, material of construction, pressure and temperature ratings, and end connections. In addition, if the valve is to be used for control purposes, additional parameters must be defined. These parameters include: method of operation, maximum and minimum flow capacity requirement, pressure drop during normal flowing conditions, pressure drop at shutoff, and maximum and minimum inlet pressure at the valve. These parameters are met by selecting body styles, material of construction, seats, packing, end connections, operators and supports.
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