DE1100417B - Pressure medium control for pipeline valves - Google Patents

Description

Fluid Control for Pipeline Valves The present invention relates to a pressure medium control for a arranged in a pipeline Main valve or the like. It has a control valve for the automatic closing of the Main valve by means of an actuator depending on a pressure drop in the pipeline and with auxiliary control means dependent on the pressure in the pipeline on, which is via a line to the part of the pipeline which is under lower pressure are connected to the control valve as a function of when the main valve closes to actuate and from an increase in pressure in this part of the pipeline so that the main valve can be opened again.

There are control valves in high pressure pipelines known that hydraulically can be opened and closed. It is also known that the rule impetus for the opening and closing of the control valves can be found in the pipeline, in which sits the shut-off valve to be regulated. Usually it is used to trigger the regulating organ the pressure difference is exploited, which is in. the pipeline between two points results, which are arranged upstream and downstream of the shut-off valve to be regulated.

It is also known to design these control valves as shut-off valves. which are closed by the regulator when the pressure in the main pipeline drops will.

An auxiliary control unit can be used to regulate the valve in the main pipeline used that essentially. consists of two shuttle valves. The lock pieces of the shuttle valve slide against the pressure of springs in passages of a partition, which divides the housing of the shuttle valve into two chambers. One of the chambers is connected to the atmosphere, while the other chamber is connected via a pipe communicates with the high pressure part of the main pipeline. The lock pieces can be influenced by a control element via rods, so that optionally the one or the other shuttle valve can be opened. From the passages of the Double-conical valve body in the partition of the shuttle valve branch lines which open into the hydraulic motor for driving the shut-off element.

The auxiliary control device is used to automatically close the shut-off valve provided with a control element, which is a working against the force of a spring Has membrane. The membrane is provided with a rod that is connected to the one before The control element described can come into operative connection when the pressure in the main pipeline sinks below a tolerable value.

However, until now it has not been possible to make such valves automatically to open again. Had to open the shut-off valves in the main pipelines appropriate valves and devices are operated by hand.

This manual operation causes a significant delay up to to reopen the shut-off valves. This can make them unnecessary and costly Faults, for example in a gas pipeline or in an oil pipeline, caused will.

It is desirable to avoid these disturbances, especially when if the pressure fluctuations. that led to the closing of the shut-off valve, are short-lived, for example when a line suddenly interferes with a Main line connected wind and the resulting pressure drops the controls for the shut-off valves to respond.

The present. The invention is based on the object of a system to create at which, after the pipeline valve due to a pressure drop in the line was automatically closed, a pressure build-up in the Line to a predetermined value, the pipeline valve automatically opens again. This object is achieved in that the lines leading to the auxiliary control means a shut-off valve, a throttle valve and a pressure relief valve included. and a storage tank between the throttle valve and the pressure relief valve is connected, the throttle valve to shut off the flow of pressure medium from the Pipeline and the auxiliary equipment connected to it Lines to Storage tank regulates when the shut-off valve is closed by closing the main valve has been opened by means of its operating device, and that in the storage container built-up auxiliary pressure via the pressure relief valve a piston and one of a two-armed lever released by a membrane influenced by the pipeline pressure actuated the auxiliary control means and then via a shuttle valve the inflow of the Auxiliary pressure medium to the motor of the valve actuation device reverses again. Here can, the pressure to which the pressure relief valve is set, the normal pressure in the main line, but it can also be set to a lower value be.

Advantageously, there is in the line between the pressure relief valve and a vent valve is arranged for the piston. The storage tank is also provided with a vent valve.

The single figure shows a schematic overview of the novel Pressure medium control for pipeline valves.

The main valve 10 is arranged between two sections 11 and 12 of a high-pressure pipeline to be shut off. It can be opened and closed by turning. Its spindle, not shown, is connected to the rotor 14 of a hydraulically driven rotary vane motor 15, which is only shown schematically. The drive medium for the motor 15 can either be taken directly from the main pipeline or from a storage device.

The rotary vane motor 15 is controlled by auxiliary control means 16, which receive their impulse from the pipeline to be shut off. As a link between the pipeline to be shut off and the. Auxiliary control means 16 is a line 19 intended. In order to receive the pulse for the auxiliary control center 116 if necessary to be able to divert the pipeline parts 11, 12 upstream and downstream of the main valve 10, the line 19 is connected to a double-acting valve 21. This contains Closing pieces 21A and 21B which are pressed by a spring 22 onto their valve seats will. Two lines 17 and 18 lead from the valve 21 to the pipe sections 11 and 12. In these lines 17 and 18 shut-off valves 20 are arranged. the Line 19 branches off between the closure pieces 21 A and 21 B from the valve 21, so that in the event of a failure or break in the main pipeline, the auxiliary control means `16 @ always" - fed from the high pressure side of the pipeline to be shut off.

With this arrangement, when there is a pressure difference between the Pipeline sections 11 and 12 are present, the higher pressure the valve 21, whereby the line 19 is connected to the corresponding pipeline section 11 or 12 will.

The line 19 is connected to a shuttle valve 16A. The shuttle valve 16A has an outlet chamber 24 which communicates with chamber 23 via passages 25 and 26 and communicates with the atmosphere via an outlet 27 and a conduit 27 '. The closure pieces 28 and 28 'are movably mounted in the passages 25 and 26, respectively. If the shuttle valve 16 A is in the neutral position according to the drawing, coil springs 31 and 31 'normally press the latches against the lower ones Ends of the passages.

A two-armed lever 32 with a handle for operating the shuttle valve 16A is rotatably mounted on an arm 33 which is attached to the housing of the valve 16A is. The pivot point of the lever 32 lies between the center lines of the two Closures 28, 28 '. On the two-armed lever 32 are a mirror image of his Pivot lugs attached, which are in operative connection with intermediate members 34, 34 '. The intermediate members 34, 34 'extend through the wall of the valve 16 A in the outlet chamber 24, where they meet with the upper parts, the closure pieces 28, 28 ', which can thus be optionally closed when the two-armed lever around his Pivot point is pivoted.

The end of the two-armed lever 32 facing away from the handle protrudes a lug 77 and via a rod 76 'to a spring under the action of a spring 78 standing piston 76 in connection, while the handle end of the two-armed lever 32 via a projection 58 and a rod 30 with one under the action of a Spring 34 standing membrane 35 is connected. The membrane spans .one through the housing parts 37, 38 formed chamber 36. Membrane 35 and piston 76 belong to the auxiliary control means 16.

The passages 25 and 26 of the shuttle valve 16 A are via lines 39 and 39 ', which branch off between the locking pieces 28, 28', with the hydraulic Motor 15 connected. The pressurized medium in the lines 39, 39 'should a liquid, for example C51, into the pressure side of the motor 15 and force out of the exhaust side of the engine into a closed circuit. the Line 39 connects passage 25 to the top of a storage tank 40, and line 39 'connects passage 26 to the upper end of a storage container 40 '. The lower end of the storage container 40 is connected via lines 41 and 42 one side of the engine in connection, while the lower end of the storage container 40 'via lines 41' and 42 'connected to the opposite side of the motor is.

For manual operation of the motor 15, a hand pump 43 and a Reversing valve 44 may be provided. In the normal control position of the system is the control valve 44 adjusted so that it bypasses the pump 43 so that the lines 41 and 42 and also the lines 41 'and 42' are directly connected to one another.

The rotor 14 of the motor 15 has two diametrically opposed Wings 45 and 46, which rotate between two fixed walls 47 and 48. In addition, two passages 100, 101 are arranged in the rotor 14, which are not the subject of the present invention.

For example, line 42 introduces pressurized C51 into the space between wall 47 and vane 45, which is connected via passage 100 in rotor 14 to the space between vane 46 and wall 48 on the other side of the rotor same pressure on corresponding sides of both wings of the rotor 14 to close the main valve 10 in a clockwise direction. The transverse passage 101 connects the spaces on the outlet sides of both wings, so that C51 is pushed out of these two spaces through the line 42 '. By reversing the flow through lines 39 and 39 ', the motor 14 is rotated counterclockwise to open the valve 10.

As the drawing shows, a filter can be installed in the line 19 51 lie, which in the usual way, for. B. on a terminal block 52 is attached. Furthermore, the line 19 is connected to a storage container 54 via a line 53 tied together. When the pressure is in two pipe sections 11 and 12 would drop so quickly as a result of a line break that there is not enough pressure would be available to operate the motor, the previously in the storage tank 54 stored pressure used to operate the motor.

The rod 30 for actuating the diaphragm 35 is normally through the force of the spring 34 is pushed away from the two-armed lever 32. Approach 58 is in Distance from the end of the rod 30 to allow an idling between rod 30 and To create approach 58, in the event that the rod 30 against the two-armed Hebe132 is pushed. The idling allows manual actuation of the lever 32 without interference the normal position of the rod 30.

The chamber 36 is in communication with the main pipeline via a line 59, a valve 60 and the lines 17 and 18. The valve 60 is divided into two chambers by a partition wall. The partition is provided with a passage in which a double locking piece 61 slides freely. The line 59 opens into the passage between the two parts of the closure piece 61. The function of the valve 60 is opposite to that of the valve 21. It creates a permanent connection between the line 59 and the low pressure side of the main pipeline because the pressure from the high pressure side of the main pipeline constantly blocks the plug 61 so that the line 59 is only in communication with the low pressure side of the main pipeline.

The line 59, in which the shut-off valve 68 is located, is still a pressure gauge 69 is connected. In the chamber 36 opposite and from Her chamber, separated by the membrane 35, opens into a line 62 to which a pressure gauge is attached 70 is connected. The Leittalg 62 opens into a storage tank 63 and is Connected to line 59 via a throttle valve 65 and line 64. Vicinity the opening of the line 64 into the line 59 is a drain valve in the line 59 67 arranged.

In order to adjust the throttle valve 65 so that a regulation of the diaphragm 35 occurs at a desired pressure drop, in order to pivot the rear end of the two-armed lever 32 to open the double valve 28, so that the main valve 10 is closed, the valve 68 is closed and that Drain valve 67 opened slowly to compensate for a pressure drop in the pipeline.

The present invention relates to the automatic control Reopen the main valve 10 after it has been due to a pressure drop in the main pipeline has been closed. This Druckabfaill was sufficient, the membrane 35 and thus the auxiliary control means 16 and the. Actuate motor 15 to close the main valve. The automatic reopening takes place after a certain period of time after the closing pressure in the main pipeline has reached a value that for a further operation is sufficient.

In the present system, the auxiliary control means 16 have: Control cylinder 75, in which a piston 76 slides against the force of a spring 78. A rod 76 ′ is attached to the piston 76 and protrudes through the cylinder cover 75. The piston rod 76 'can with a shoulder 77 at the end of the remote from the handle two-armed lever 52 cooperate. Between the piston rod 76 'and the extension 77 exists. Distance to a defined idle between the approach and the To enable piston rod 76 '. A line leads through the cover of the cylinder 75 79 outdoors. In the rest position, the piston 76 is in the position shown in the figure, rest position determined by the pressure of the spring 78. In the bottom of the cylinder 75 The line 80 opens, which connects to the line 59 via the line 81 manufactures.

In the line 80, a valve 82 and a pressure relief valve 83 are provided, which opens at a predetermined minimum pressure. A throttle valve 84 and a shut-off valve 85 are located in the line 81. Between the throttle valve 84 and the pressure relief valve 83, a line branches off from the line 81 to the storage container 86, which has a vent valve 87.

The shut-off valve 85 is connected by suitable mechanical or other means to the main valve 10 or, as the figure shows by a dot-dash line, to the rotor 14 of the hydraulic motor 15, that when the rotor 14 rotates clockwise to Closing of the main valve 10 has ended, is automatically opened.

As soon as the shut-off valve 85 has opened, any pressure present in the main pipeline on the low-pressure side of the main valve 10 causes a flow in the line 81 to the throttle valve 84. The throttle valve 84 is more open than the vent valve 87, so that pressure builds up in the container 86 after a predetermined time, which depends on the size difference of the passages 84 and 87.

The pressure relief valve 83 is set so that it opens when the pressure prevailing in line 81 has increased to a value that was previously set as the minimum pressure for suitable work requirements in the main line has been. This value can be equal to or slightly less than the original before the pressure drop and the closing of the valve 10 in the main pipeline been pressure. When this predetermined pressure is reached, the pressure relief valve opens 83. The piston 76 moves against the force of the spring 78 and actuated via the Piston 76 'the auxiliary control means 16 in such a way that the flow through the lines 39 and 39 'changes, whereby the main valve 10 is opened again.

When the motor 15 begins to open the valve, the movement closes of the rotor 14 automatically closes the shut-off valve 85 Pressure initially keeps the pressure relief valve 83 open, causing the piston 76 remains actuated. After the valve 10 has fully opened, the pressure in the Storage tank 86 is drained through vent valve 87. It then closes the pressure relief valve 183. The pressure behind piston 76 is released through the vent valve 82 drained, after which the piston 76 returns to its rest position. The springs 31 and 31 'make the shuttle valve 16A return to the rest position. The system is then ready for a new main valve closing and opening cycle when another pressure drop occurs.

If, after the main valve 10 has been closed, as a result of a pressure drop in the main pipeline, the pressure does not build up again to the predetermined minimum required for opening the pressure relief valve 83, as is the case in the case of a pipeline rupture, any pressure present in the line 81 goes through the throttle valve 84 into the container 86 and exits through the vent valve 87 from the container without the pressure relief valve 183 is opened. The main valve 10 remains closed until the damage is repaired.

Claims (3)

PATENT CLAIMS: 1. Pressure medium control for one in a pipeline arranged main valve or the like, with a control valve for automatic closing of the main valve by means of an actuator depending on a Pressure drop in the pipeline and with auxiliary control means dependent on the pressure in the pipeline, via a line to the part of the pipeline which is under lower pressure are connected to the control valve as a function of when the main valve closes to actuate and from an increase in pressure in this part of the pipeline so that the main valve can be opened again, characterized in that the auxiliary control means (16) lines (59, 81, 80) leading a shut-off valve (85), a throttle valve (84) and a pressure relief valve (83) included and between the throttle valve (84) and the pressure relief valve (83) connected to a storage container (86) is, wherein the throttle valve (84) to shut off the flow of pressure medium from the Pipeline (11, 12) and the auxiliary lines (59, 81) connected to it to Storage tank (86) regulates when the shut-off valve (85) by closing the Main valve (10) has been opened by means of its actuating device (15), and the auxiliary pressure built up in the storage container (86) via the pressure relief valve (83) a piston (76) and a membrane influenced by the pipe pressure (35) released two-armed lever (32) of the auxiliary control means (16) actuated and thereupon the supply of the auxiliary pressure medium to the engine via a shuttle valve (16A) the valve actuating device (15) reverses again. 2. Control according to claim 1, characterized in that in the line (80) between the pressure relief valve (83) and the piston (76) a vent valve (82) is arranged. 3. Control according to claim 1 or 2, characterized in that the storage container (86) a vent valve (87) is connected. Considered publications: U.S. Patent No. 2,738,945.