JPH0372872B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an actuator for a gas pipeline valve, and more specifically, the present invention relates to an actuator for a gas pipeline valve, and more specifically, the present invention is equipped with a line brake device that automatically closes the valve when the gas pressure in the pipeline drops below a predetermined value. Regarding valve actuators, there is also a line brake that automatically closes the valve when the gas pressure in the pipeline drops at a rate greater than a preset rate of descent for a preset period of time or more. The present invention relates to a valve actuator equipped with a device.

FIG. 1 shows, as an example of a valve actuator, the configuration of a gas hydraulic actuator used as an actuator for opening and closing a gas pipeline ball valve equipped with a conventional line brake device.

In this actuator, the valve stem 3 of the ball valve body 2 provided in the pipeline 1
is rotated by 90 degrees at a constant speed by the arm 31 of the Scotch yoke mechanism included in the actuator body 30 to open and close the valve. That is, in response to the valve opening/closing signal, the gas pressure of the pipeline is transmitted to the pressure vessel 23 or 24, thereby
The hydraulic oil in the container is pressurized and sent into the cylinder chamber of the actuator to move the piston 32 and the piston 33, thus rotating the arm in response to the stroke of the piston rod. Note that the illustrated arm position indicates a state in which the ball valve is open.

In order to transmit the gas pressure of the pipeline to the pressure vessel, gas conduits 11 and 12 from upstream and downstream of the pipeline are connected to the shuttle valve 13 via stop valves 4 and 5, respectively, with the valve body 2 in between. It is connected to a pair of two-position solenoid valves 21 and 22 housed in a housing 20. The illustrated position of these solenoid valves is a neutral position, with the port of the gas conduit 14 blocked.

In one electromagnetic valve 22, when a signal to close the valve is input to the terminal 7, the solenoid 22s is energized and the spool moves, and the gas conduit 14
passes through the shuttle valve 44 to the gas pressure operated switching valve 42
and connect the gas conduit 14 to its branch conduit 4.
A circuit is formed which connects to the gas conduit 16 via 3a. As a result, the gas pressure in the pipeline is transmitted to the pressure vessel 24 through the gas conduits 14, 43a, and 16, pressurizing the hydraulic oil within the vessel. The pressurized hydraulic oil enters the cylinder 35 of the actuator body through the flow control valve 26 and the switching valve 27, pushes the piston and piston rod to the right, rotates the valve stem by the arm of the Scotch yoke mechanism, and opens the ball valve. close.

When the solenoid 21s of the other solenoid valve 21 is excited, the other solenoid valve 21 transmits the gas pressure to the gas pressure operated switching valve 41 via the switching valve 40, and similarly connects the gas conduit 14 to the pressure vessel 23 via the gas conduits 43b and 15. Form a circuit to connect. As a result, the pressurized hydraulic oil in the container is sent to the cylinder chamber 34 of the actuator body via the flow control valve 25 and the switching valve 27, pushing the piston rod to the left and opening the valve.

The configuration and operation of a conventional line brake device are as follows. A gas conduit 17 is connected to the pipeline via a stop valve 6, and a gas conduit 18 branched from this conduit is connected to a check throttle valve 5.
0 to the sensing tank 51, and the gas pressure in the sensing tank is kept equal to the gas pressure in the pipeline. The gas conduit 17 is a diaphragm switching valve 53 equipped with a diaphragm 52.
is connected to the diaphragm chamber 54 of
It is connected to a port 54a that connects to a gas conduit 56. This port 54a is normally blocked, and the diaphragm chamber and port 54a
is normally kept equal to the pipeline gas pressure. A secondary side 55 of the switching valve 53 is connected to the sensing tank by a gas conduit 19.

Here, when the gas pressure of the pipeline decreases, the diaphragm chamber of the switching valve 53 directly connected to the pipeline is depressurized, but the secondary side is connected to the sensing tank and is connected to the pipeline. Since the throttle valve 50 with a check is interposed therebetween, the drop in gas pressure on the secondary side is small, and as a result, a pressure difference is generated between the diaphragm chamber and the secondary side. This differential pressure causes the switching valve 53 to move to the left and change its position, thus allowing gas from the gas conduit 17 to enter the switching valve 42 via the port 54a, the gas conduit 56 and the shuttle valve 44. At this time, the switching valve 40 is also switched at the same time. Therefore, as described above, this switching valve 42 forms a circuit connecting the gas conduits 14 and 43a to the gas conduit 16 to transmit gas pressure to the pressure vessel 24,
Pressurize the hydraulic fluid and close the valve.

However, in the above-mentioned line brake device, the drop in gas pressure in the pipeline is mechanically detected by the diaphragm switching valve 53, so the accuracy is poor, and if the gas is corrosive,
Its use is difficult. Furthermore, in some cases,
It may be desirable to close the valve only when the gas pressure in the pipeline continues to drop for a predetermined period of time. The valve is closed as soon as the gas pressure drops below a predetermined value.

The present invention was made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a valve actuator equipped with a line brake device that operates accurately when the gas pressure in the pipeline drops below a predetermined value. In particular, it is an object of the present invention to provide a pipe actuator equipped with a line brake device that operates only when the gas pressure in the pipeline continues to decrease for a predetermined period of time.

The actuator for a valve according to the present invention connects gas from a gas pipeline to a solenoid valve through a gas conduit, and energizes or demagnetizes a solenoid included in the solenoid valve, thereby directly directing the gas through the solenoid valve to the cylinder of the actuator. Pressurize the working fluid by introducing the gas into the chamber or into a pressure-resistant container, and send this working fluid to the cylinder chamber of the actuator to drive the valve stem of the valve installed in the gas pipeline to open and close the valve. The valve actuator is provided with a gas pressure detection device for the gas pipeline, and when the detected gas pressure becomes less than a preset gas pressure, the solenoid of the solenoid valve is energized or demagnetized to close the valve. It is characterized by the following.

The present invention will be described below based on drawings showing examples.

FIG. 2 shows a gas-hydraulic actuator for a ball valve as an example of a valve actuator equipped with a line brake device according to the present invention, but for the sake of simplicity, some components common to FIG. 1 are omitted. and shows the configuration added by the present invention. Therefore, the same reference numbers as in FIG.
Figures show the same elements or configurations and operate in the same manner.

In the present invention, the line brake gas conduit 17 of the gas pipeline is connected to a gas pressure detection device 60 of the gas pipeline, for example, a pressure gauge,
Gas pressure is thereby detected. This detected gas pressure is input to the control device 61. The control device controls the solenoid valve 22 by the control circuit 62 when the detected gas pressure becomes equal to or lower than a preset gas pressure.
The solenoid 22s is energized, the gas conduit 14 from the gas pipeline is connected to the gas conduit 16, and thus, as described above, the hydraulic oil in the pressure container is passed through the flow control valve 26 and the switching valve to the cylinder of the actuator body. It sends it to chamber 35 and closes the valve.

In the present invention, preferably, in the control device, when the input detected gas pressure continues to drop at a rate greater than a preset rate of decline for a preset time or more, For the first time, a signal is sent to the solenoid valve 22 to energize its solenoid.

That is, another actuator according to the present invention connects gas in a gas pipeline to a solenoid valve through a gas conduit, and energizes or demagnetizes a solenoid included in the solenoid valve, thereby directly directing the gas through the solenoid valve to the actuator. into the cylinder chamber of
Or in a valve actuator that opens and closes the valve by introducing the gas into a pressure-resistant container to pressurize the working fluid, and sending this working fluid to the cylinder chamber of the actuator to drive the valve stem of the valve installed in the gas pipeline. , the gas pressure detection device for the gas pipeline is provided, and when the detected gas pressure drops at a rate greater than a preset rate of decline over a preset predetermined time, the solenoid of the solenoid valve is activated. It is characterized in that the valve is closed by excitation or demagnetization.

In this actuator, instead of simply closing the valve immediately due to a drop in gas pressure, the amount of drop in gas pressure per unit time, that is, the rate of drop in gas pressure, is determined based on the detected gas pressure, and this is determined in advance. is higher than the set predetermined descent speed,
Moreover, the electromagnetic valve 22 is operated only when the operation continues for a preset predetermined time.

In addition, according to the actuator of the present invention, normal valve opening/closing without using a line brake device is possible.
The solenoid valve 21 or 22 may be excited by a signal from the terminal. For example, if the solenoid valve 22 is energized by a circuit not shown in FIG. A circuit can be formed that connects to the conduit 15 and thus the valve can be opened.

The above description has been about actuators for gas-hydraulic ball valves, but gas-hydraulic gate valves differ from ball valves in that the valve stem connected to the valve is driven up and down by the actuator to open and close the valve. Therefore, it is clear that the present invention is not limited to ball valves, but is equally applicable to gate valves. Furthermore, it is clear that the present invention is applicable not only to gas-hydraulic actuators but also to gas direct-acting actuators that use pipeline gas directly as the working fluid for the actuator.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram showing an example of an actuator for a gas-hydraulic valve equipped with a conventional line brake device, and FIG. 2 is a diagram showing an example of an actuator for a gas-hydraulic valve equipped with a line brake device according to the present invention. FIG. 1... Pipeline, 2... Valve body, 3... Valve stem, 11, 12, 14, 15, 16, 1
7, 18, 19... Gas conduit, 21, 22... Solenoid valve, 23, 24... Pressure resistant container, 25, 26... Flow control valve, 27... Switching valve, 30... Actuator main body, 31... Arm, 41, 42... Gas Operation switching valve, 50... Throttle valve with check, 51... Sensing tank, 52... Diaphragm, 53... Diaphragm switching valve, 54... Diaphragm chamber, 55... Secondary side, 60... Gas pressure detection device, 61... Control device, 6
2...Control circuit.

Claims (1)

[Claims] 1. Gas in a gas pipeline is connected to a solenoid valve through a gas conduit, and by energizing or demagnetizing a solenoid of the solenoid valve, the gas passes through the solenoid valve,
Send the above gas directly to the cylinder chamber of the actuator, or introduce the above gas into a pressure-resistant container to pressurize the working fluid, and send this working fluid to the cylinder chamber of the actuator to control the valve stem of the valve installed in the gas pipeline. In a valve actuator that is driven to open and close a valve, the gas pressure detection device for the gas pipeline is provided, the detected gas pressure is input to a control device, and the control device
When it is detected that the gas pressure has decreased at a rate greater than a preset rate of decrease over a preset period of time, the control device energizes or demagnetizes the solenoid of the solenoid valve. An actuator for a valve, characterized in that the valve is closed.