KR100526986B1 - Cooling device of air operated valve system - Google Patents

Abstract

The present invention relates to a cooling device of an air-driven valve system for facilitating smooth fluid control by rapidly cooling heat transferred to a valve from a high temperature fluid conveyed onto a pipeline of a plant.

The present invention is a current-pressure converter for converting the current applied from the valve control unit in the form of a pneumatic signal, a positioner whose opening degree is determined by the pneumatic signal converted in the current-pressure converter, and installed on the plant pipe line casing A valve having a valve body for opening and closing the flow path formed therein; an actuator for opening and closing the flow path in the valve by operating the valve body by control air supplied through the positioner; and control air from the external source to the actuator side through the positioner. In the air-driven valve system including a control air supply unit for supplying, an air flow path is formed inside the valve body, the air flow path communicates with the pipe branched from one side of the supply pipe of the control air, the one side branch pipe The on / off valve for regulating the flow path of the branch pipe and the on / off valve Characterized in that a control unit for opening and closing valves.

Description

Cooling device of air operated valve system

The present invention relates to an air-driven valve system in which valves are opened and closed by control air, and more particularly, smooth fluid control is achieved by rapidly cooling heat transferred to a valve from a high temperature fluid transferred onto a plant pipe. It relates to a cooling device of the air-driven valve system for planning.

As is well known, an air operated valve system is one of the representative valve systems for controlling high temperature and high pressure fluids flowing into various pipelines installed in large plants such as power plants. It not only controls the direction, direction, etc. but also performs the main functions such as opening and closing of the flow path, throttling, check, and overpressure prevention.

Such an air-driven valve system is divided into a diaphragm type and a cylinder type according to the type of actuator, and is further classified into a plug type and a disc type according to the type of the valve body.

1 is a conceptual view illustrating one embodiment of an air-driven valve system to which a diaphragm actuator is applied.

As shown, the air-driven valve system includes a current-pressure converter 1 for converting a current applied from a valve control unit (not shown) into a pneumatic signal form, and a pneumatic signal converted from the current-pressure converter 1. The valve body 4c is operated by the positioner 2 whose opening degree is determined, the valve 4 provided on the pipeline 7 of the plant, and the control air supplied through the positioner 2 to operate the valve 4c. Actuator (5) for opening and closing the flow path in the (), and a control air supply unit (not shown) for supplying the control air to the actuator (5) side through the positioner (2) from an external supply source (not shown). Here, the actuator 5 is provided with a diaphragm 5a which is returned to its original position by the elastic force when the external force (that is, the supplied control air) is removed, and the positioner 2, the actuator 5, and the control air supply unit ( (Not shown) communicate with each other through the supply pipe.

In addition, the valve 4 is a casing 4a provided on the pipeline of the plant, a valve seat 4b mounted on the flow path inside the casing 4a, and a plug-type valve body for opening and closing the valve seat 4b. 4c and the stem 4d connected to the upper part of the valve body 4c.

With this configuration, when the current applied from the valve control unit (not shown) is converted into a pneumatic signal form proportional to the amount of current in the current-pressure converter 1, the positioner is converted by the pneumatic signal converted in the current-pressure converter 10. (2) determines the opening degree, so that the control air is introduced into the actuator (5) side through the positioner (2) from the control air supply (not shown).

When the control air flows in or out of the actuator 5 in this way, the diaphragm 5a of the actuator 5 is operated to move the stem 4d of the valve 4 up and down, and to move the stem 4d up and down. As a result, the opening ratio of the conduit 7 of the plant is determined as the valve body 4c opens and closes the valve seat 4b.

However, such a conventional pneumatically actuated valve system has a high temperature of heat flowing through the valve body 4c and the valve seat 4b while the hot fluid flowing on the conduit 7 of the plant passes through the valve body 4c and the valve. There was a problem that the valve body 4c is thermally expanded due to the high temperature heat transferred to the seat 4b, and thus the valve seat 4b cannot be opened and closed normally.

In more detail, when the valve is in a closed state, a phenomenon in which the valve body 4c thermally expands and adheres to the valve seat 4b occurs due to the high temperature heat transmitted from the high temperature fluid, causes the valve opening operation to occur. Or delays may result in improper fluid control.

In addition, when the valve is in the open state, the valve body 4c expands due to the high temperature heat transmitted from the high temperature fluid so that the valve body 4c cannot be inserted into the valve seat 4b during the valve closing operation. Damage due to impact occurs between the elements 4c and 4b, thereby shortening the valve life.

Therefore, the present invention has been made to solve the above problems, by forming an air flow path inside the valve body by applying a structure forcibly injecting air to cool, thereby preventing the expansion of the valve body more smoothly It is an object of the present invention to provide a cooling device of an air-driven valve system capable of performing fluid control and preventing damage to the valve body to increase its life.

The present invention for achieving the above object is a current-pressure converter for converting the current applied from the valve control unit in the form of a pneumatic signal, a positioner whose opening degree is determined by the pneumatic signal converted in the current-pressure converter; A valve having a valve body installed on the plant's pipeline and opening and closing the flow path formed inside the casing; an actuator for opening and closing the flow path in the valve by operating the valve body by control air supplied through the positioner; and an external supply source. In the air-driven valve system comprising a control air supply for supplying control air to the actuator side through the positioner, the air flow path is formed inside the valve body, the air flow path is branched from one side supply pipe of the control air It communicates with the pipe, and on one side of the branch pipe, the flow path of the branch pipe is interrupted. It is characterized by having a valve for opening and closing controller for controlling the on-off valve and the on-off valve.

Preferably, one side of the pipeline of the plant is provided with a temperature sensor electrically connected to the on-off valve control unit.

Preferably, the on-off valve is characterized in that it is controlled to open and close at a predetermined time interval by the control unit for the on-off valve.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 shows a cooling device of the air drive valve according to an embodiment of the present invention.

As shown, the present invention has a degree of opening by the current-pressure converter 12 for converting the current applied from the valve control unit 11 into a pneumatic signal and the pneumatic signal converted in the current-pressure converter 12 A valve 4 having a positioner 13 to be determined and a valve body 4c (see FIG. 1) provided on the pipeline 17 of the plant to open and close a flow path formed inside the casing 4a (see FIG. 1). 1), an actuator 15 for operating the valve body 4c of the valve 4, a supply pipe, a regulator, and a supply pipe for supplying control air from the external source to the actuator 15 through the positioner 13; In the air-driven valve system comprising a control air supply unit 16 made of a filter or the like,

An air flow path 10 is formed inside the valve body 4c, the cooling air supply pipe 19 branches from one side of the supply pipe 16a of the control air supply unit 16, and this cooling air supply pipe 19 and the air flow path 10 communicate with each other, the on-off valve 20 and the on-off valve 20 to control the flow path of the cooling air supply pipe 19 to one side of the cooling air supply pipe 19. It is characterized in that the on-off valve control unit 25 for controlling the.

On the other hand, the control air supply unit 16 communicates with the positioner 13 and the actuator 15 through the supply pipe 16a.

According to the present invention, a predetermined air flow path 10 is formed inside the valve body 4c, and the air flow path 10 is forcibly supplied with air for cooling to flow to the plant pipe 17 of the plant. By cooling the high temperature heat transmitted from the fluid to the valve body 4c, the structure which prevents thermal expansion which may generate | occur | produce on the valve body 4c is characterized.

In addition, the configuration for forcibly supplying air to the air flow path 10 includes a cooling air supply pipe 19 branched from one side of the supply pipe 16a of the control air supply unit 16, and the cooling air. On the supply pipe 19 is composed of an on-off valve 20 and a control unit 25 for the on-off valve.

The on-off valve 20 is preferably a solenoid valve suitable for controlling the flow of cooling air supplied to the air flow path 10 of the valve body 4c.

The on / off valve control unit 25 controls the open / close frequency or the open / close amount of the open / close valve 20 to supply an appropriate amount of cooling air according to the state of the valve body 4c.

Preferably, one side of the plant's pipeline 17 is provided with a temperature sensor 30, the temperature sensor 30 for the on-off valve by measuring the temperature of the fluid flowing in the pipeline 17 of the plant in real time The control unit 25 transmits to the control unit 25, and the on / off valve control unit 25 controls the opening / closing frequency or opening / closing amount of the opening / closing valve 20 according to the temperature measured by the temperature sensor 30, thereby allowing air flow in the valve body 4c. It is configured to adjust the supply amount of the cooling air flowing into the path (10).

Alternatively, instead of the configuration of adjusting the supply amount of cooling air using the above-described temperature sensor, by controlling the opening and closing operation of the open-close valve 20 to be performed at a specified time interval by the on-off valve control unit 25, It may be configured to adjust the supply amount of the cooling air flowing into the air flow path 10 of the sieve (4c).

Meanwhile, the present invention is not limited to the air driven valve system to which the diaphragm actuator illustrated in FIG. 1 is exemplarily illustrated, and may be applicable to various types of air driven valve systems such as a cylindrical actuator applied thereto.

3 and 4, the configuration of the air flow path 10 of the present invention is a plug type valve body 4c (see Fig. 3) or a disk type valve body 4c (Fig. 3). It may also be applicable to various types of valve body.

The operation of the present invention configured as described above will be described below.

First, when the current applied from the valve control unit 11 is converted into a pneumatic signal form proportional to the amount of current in the current-pressure converter 12, the positioner 13 by the pneumatic signal converted in this current-pressure converter 12 Determining the opening degree, the control air is introduced from the control air supply unit 16 to the actuator 15 through the positioner (13).

When the control air flows into or out of the actuator 15, the actuator 15 operates to move the stem 4d up and down, so that the valve body 4c of the valve 4 moves the valve seat 4b. The opening and closing rate of the pipeline 17 of the plant is determined by opening and closing.

At this time, when high temperature heat is transferred from the high temperature fluid flowing into the plant pipe 17 of the plant to the valve body 4c and the valve seat 4b, the on / off valve 20 is opened by the on / off valve control unit 25. Partially classified cooling air flows into the air flow path 10 of the valve body 4c through the cooling air supply pipe 19, so that the valve body 4c is cooled.

Next, after the cooling of the valve body 4c is completed, the cooling air is discharged to the outside through the outlet of the air flow path 10.

The present invention as described above, by forming an air flow path inside the valve body by applying a structure forcibly injecting air to cool, it is possible to perform a more smooth fluid control by preventing the thermal expansion phenomenon of the valve body, It has the effect of preventing the damage of the sieve and increasing the life.

In the above, the present invention has been illustrated and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art to which the present invention pertains may vary without departing from the spirit of the technical idea of the present invention described in the claims below. It may be changed.

1 is a partial cross-sectional view illustrating an exemplary pneumatically actuated valve system to which a general diaphragm actuator is applied.

Figure 2 is a conceptual diagram showing a cooling device of the air-driven valve system according to an embodiment of the present invention.

3 is a cross-sectional view showing a state in which the cooling device of the present invention is applied to a plug-shaped valve body by way of example.

4 is a cross-sectional view illustrating a state in which the cooling device of the present invention is applied to a valve body in a disk form.

Explanation of symbols on the main parts of the drawings

10 air flow path 11 valve control unit

12 current-to-pressure converter 13 positioner

15: actuator 16: control air supply

19: cooling air supply pipe 20: on-off valve

25: control unit for the closing valve

Claims (3)

A current-pressure converter for converting the current applied from the valve control unit into a pneumatic signal, a positioner whose opening degree is determined by the pneumatic signal converted by the current-pressure converter, and a pipe installed in the plant's pipeline and formed inside the casing. A valve having a valve body for opening and closing a flow path, an actuator for operating the valve body of the valve, and a control air supply unit for supplying control air to the actuator side through a positioner from an external source. An air flow path is formed inside the valve body, and the air flow path communicates with a pipe branched from one side of the supply pipe of the control air, and on one side of the branch pipe, an opening / closing valve for regulating the flow path of the branch pipe and the open / close valve. Cooling device of the air-driven valve system characterized in that it comprises a control unit for the on-off valve for controlling the. The method of claim 1, Cooling apparatus of the air-driven valve system, characterized in that the one side of the plant pipeline is provided with a temperature sensor electrically connected to the on-off valve control unit. The method of claim 1, The on / off valve is controlled by the on / off valve control unit to be controlled to open and close at a predetermined time interval.