DE3906888A1 - Control device for a safety valve - Google Patents

Abstract

In order to control a safety valve (4), working on the pressure-relief principle, of a pressure vessel (17) in a safe and controlled fashion, provision is made for a control device in which the pressure vessel (17) is connected via a measuring line (16) to the piston space (15) of a piston (14). The piston (14), which is movable in the piston space (15) by the prevailing pressure, acts on a valve plate (9) which is spring-loaded in a valve space (2a) on an opening (11) provided with a valve seat (8). The control space (3) of the safety valve (4) is connected to the valve space (2a) via a control line (2). The opening (11) is adjoined by the blow-out line (5). At a preset pressure in the pressure vessel (17), the piston (14) opens the opening (11) closed by the valve plate (9), and the control space (3) of the safety valve (4) is relieved of pressure via the control line (2) and the blow-out line (5). The safety valve (4) opens and the pressure in the pressure vessel (17) is thereby lowered. <IMAGE>

Description

The invention relates to a control device for an after Relief principle working safety valve of a Druckbe container, in which the pressure vessel via a measuring line with the Piston chamber of a piston is connected to a valve plate in egg nem valve space on an opening provided with a valve seat is spring loaded, one with one end to the control room of the Safety valve connected control line and an off Blow line and means for non-positive connection between the piston and the valve plate are provided.

From EP-A-01 10 210 is a device for controlling a Safety valves known that work on the principle of relief is controlled. An auxiliary valve that works as a pressure relief valve is formed and opens in the direction of its flow, is to relieve the control chamber of the safety valve see. The auxiliary valve is a piston with two piston spaces assigned, the first with the pressure chamber to be monitored, the second with the control room and both pressure rooms with each other are connected via a throttle. If that helps valve opens slightly in the event of overpressure, the pressure drops in the steering wheel space of the safety valve. This will make the piston rich tion of the auxiliary valve accelerates and stops with its piston open the auxiliary valve. The interactions between hydraulic and mechanical function lead to instability in operation, which is particularly problematic when closing are.

The object of the invention is based on this knowledge based on a control device of the type mentioned admit that largely independent of hydraulic influences sen works so that a safe, controlled opening and Closing is achieved even at high pressures.  

This task is based on the tax mentioned above device according to the invention solved in that the other end the control line is connected to the valve chamber and the off Blow line outside the valve chamber to the opening on the Ven tilsitz is connected.

The training according to the invention results in a particular simple design of the control device. It only contains few moving parts, which ensures a high level of functional reliability is given. It is also self-closing. This is particularly important for use in nuclear technology Investments. Furthermore, there are no thermal loads on the measurement line on, whereby the control device for retrofit stungen in old systems is very suitable.

The piston is advantageously under the pressure of a spring, whereby the control device has a more uniform tax character teristik receives.

A particularly useful training results when Means for the positive connection is attached to the piston arranged piston rod and / or one arranged on the valve plate Tappet is provided. This makes the structure simple anyway the control device advantageously improved.

It is particularly favorable if as a means for the frictional connections sige connection serves a ball joint, the ball in one Pan on the valve plate and its pin as a piston rod is formed or when the ball in a pan on the piston and whose pins are arranged on the valve plate. The tax direction receives a distinctive tax character in this way Statistics, which is particularly improved for the closing process.

The piston rod and / or the pin is expediently in stored in a bearing that has a bellows seal. The To This further increases the reliability of the control device.  

In a further embodiment, the piston can be used as a stepped piston ben be formed with a first and second piston space, with each other via lines and a pilot control device are connected. So the control device for special Applications with selected control areas can be used.

A device can advantageously be provided with the valve disk be connected to detect the position of the valve plate. There is a simple function control of the control unit tion possible.

The invention is described below with reference to the drawings illustrated explanations explained. Show it:

Fig. 1 is a control device for a safety valve of a pressure vessel,

Fig. 2 shows a further control device with pilot control device.

In Fig. 1, a control device 1 according to the invention can be seen. A control line 2 is connected at one end to a control chamber 3 of a safety valve 4 . This safety valve 4 has a piston 3 a with a bore 3 b, through which the control chamber 3 with a cylindrical chamber 3 c ver prevented. In this cylinder space 3 c opens a line 3 d , which is connected to the pressure vessel 17 . Furthermore, the cylinder chamber 3 c has an outlet 3 e , which can be closed by a valve plate 3 f connected to the piston 3 a . The safety valve works on the relief principle.

The other end of the control line 2 is connected to a valve chamber 2 a , which is assigned a blow-out line 5 . In the valve chamber 2 a , a valve 6 is formed by a valve plate 9 which is sprung onto a valve seat 8 by means of a spring 7 . The valve plate 9 is guided axially by a spindle 10 a . The valve chamber 2 a is connected to the blow-out line 5 through an opening 11 provided with the valve seat 8 . By actuating the valve plate 9 against the spring force, the valve 6 is opened, whereby a medium flow from the control chamber 3 , which is pressure-leading, to the blow-out line 5 is possible. The valve 6 also has a plunger 10 b , to which an actuating device 12 connects axially. This actuating device 12 has a piston 14 sprung onto a stop 13 . A piston chamber 15 is assigned to the piston 14 and is connected to the pressure vessel 17 to be monitored via a measuring line 16 . The spring of the piston 14 is brought about by a second spring 18 . The possibility is provided that the spring force can be adjusted by means of a nut 19 . Between the piston 14 and the valve plate 9 , means are provided for a positive connection. For example, here are disposed on the valve plate 9 follower 10 b and a ben 14 arranged on the piston rod 20 shown in Col. distance from each other easily. Partial training without plunger 10 b or without piston rod 20 are also possible.

Increases in the pressure vessel 17 and thus in the piston chamber 15 of the pressure, the piston 14 is moved in the direction of the valve 6 be. The piston rod 20 then hits the plunger 10 b and exerts a force on the valve plate 9 . The valve 6 is opened, whereby the pressure in the control chamber 3 via the Steuerlei device 2 and the blow-out line 5 is reduced. Due to the pressure in the cylinder chamber 3 c of the safety valve 4 , the piston 3 a and thus the valve plate 3 f is moved into the open position, a connection being established between the line 3 d and the outlet 3 e . By opening the safety valve 4 , the pressure in the pressure vessel 17 is reduced. After the pressure in the pressure vessel 17 drops below a predetermined value, the piston 14 and the valve disk 9 move back into their normal position. The opening 11 of the valve 6 is closed again. Since the valve 6 is designed so that it opens against the direction of flow, the closing of the valve 6 is supported by the medium flowing through. By closing the valve 6 , a pressure build-up in the control room 3 via the bore 3 b is possible again. After pressure build-up in the control room 3 , the safety valve 4 closes automatically.

The control device 1 is very simple and has only a few moving parts. The valve 6 is directly opened by the piston 14 without the interposition of an additional control element. Reliability is significantly increased by reducing the number of moving parts. It is particularly advantageous that the piston chamber 15 and the measuring line 16 are not flowed through by the pressure medium. This ensures that the control device 1 does not have an unnecessarily high thermal load. As a result, the control device 1 is particularly suitable for retrofitting in old systems, since no changes to the measuring line 16 need be provided. The stable physical states of the print medium also improve the operating behavior when opening and closing.

In a further variant, the actuating device 12 can also be provided with a piston 14 which has a further piston chamber 15 b . The further piston chamber 15 b is connected to the piston chamber 15 via a channel 21 . In an embodiment with two piston rods 20 , 20 a , which have different diameters, there is always a resultant force in the opening direction, which changes in proportion to the pressure in the pressure vessel 17 . The force F results from the formula

F = P · (A ₁ - A ₂ ),

where P is the pressure in the pressure vessel 17 and A ₁ and A _{2 are} the piston surfaces formed on the respective side of the piston rods 20 , 20 a . The channel 21 can also be arranged outside the piston 14 .

In FIG. 2, a further embodiment of the control device shown. 1 With the valve plate 9 Einrich device 22 is connected to detect the position of the valve plate. This can be provided, for example, by means of a coil 23 a arranged around the spindle 10 a , which is connected via a line 23 b to a signaling device 23 c . This enables the respective position of the control device 1 to be checked. In addition to the inductive principle of position detection shown, for example, other functional principles, such as mechanical, are also possible.

In the embodiment shown, the valve disk 9 is piston-shaped for flow reasons. In addition, it gives itself an improved guidance of the valve plate 9 .

The control device 1 has between the valve plate 9 and the piston 14 b means for a non-positive connection. This provides a safe control function of the control device 1 in the opening and closing directions. A ball joint 24 , the ball 24 a of which is arranged in a socket 24 b on the valve plate 9 and the pin 24 c of the piston 14 b are used as the means for the force-locking connection. The arrangement of the ball joint 24 can also be reversed, that is, with the pin 24 c on the valve plate 9 and with the socket on the piston 14 b . Such a connection allows the device 1 to function reliably.

In addition, by dimensioning a game between the ball 24 a and the socket 24 b in the ball joint 24, a hysteresis between opening and closing during the control process can be achieved. This corresponds to an embodiment, as already shown in Fig. 1 between the plunger 10 b and the piston rod 20 .

The piston rod 20 and the pin 24 c are mounted in bearings, each of which has a bellows seal 26 . This further increases the reliability of the control device 1 .

The piston 14 a , 14 b is carried out in two stages in this example. The first part of the piston 14 a is arranged in the piston chamber 15 a . The second part of the piston 14 b is assigned to the piston chamber 15 b . This design identifies the piston as a piston. The two piston chambers 15 a , 15 b are connected via lines 27 a , 27 b and a pilot control 28 for fast actuation of the piston 14 a , 14 b . The pilot control device 28 is designed in the manner of a pressure relief valve, which is provided with an adjustable additional electromagnetic load. The pilot control device 28 contains a Überdruckven valve 29 , which is arranged between the line 27 a and 27 b .

The piston chamber 15 a from the pressure vessel 17 via the measuring line 16 pressure causes a force on the small piston surface of the piston 14 a . The piston surface is dimensioned such that opening the valve 6 is not yet possible. At the same time, the pressure is applied via line 27 b to the pressure relief valve 29 of the pilot control device 28 . When the predetermined pressure value is exceeded, the pressure relief valve 29 opens and opens the way via the line 27 a to the piston chamber 15 b . With the piston 14 b , the effective piston area of the arrangement is increased. Only when both piston chambers 15 a , 15 b are pressurized, it is possible that the pistons 14 a , 14 b are moved in the opening direction of the valve 6 against the spring force of the spring 18 and against the pressure on the valve disk 9 . The piston surfaces are specially dimensioned for this. About the piston rod 20 and the ball joint 24 , the valve 6 is opened against the flow direction of the medium to be controlled. The medium is then blown out via the blow-out line 5 . This has the result that the control chamber 3 of the safety valve 4 is suddenly relieved, the safety valve 4 is opened and pressure is released from the pressure vessel 17 . Due to the reduced differential pressure between the control line 2 and the blow-out line 5 , the closing force exerted on the valve plate 9 of the medium flowing through is reduced. However, in order not to hinder a closing of the valve 9 , the forces for opening the valve 9 must be reduced. This is done by that when the valve is open, the first part 9 of the piston 14 a line b closes with its head part 27, whereby the front of control device 28 and therefore the piston chamber 15 is not more b is activated. It is now only the piston surface of the piston 14 a effective for keeping the valve 9 open. The pressure and spring forces of the control device 1 are prepared for the closing process.

If the operating pressure in the pressure vessel 17 has dropped again to a given value, the pistons 14 a , 14 b return to their original position, with the valve plate 9 being retracted into the closed position via the ball joint 24 , so that the valve 6 is closed becomes. The pilot control device 28 is therefore only necessary for opening the valve 9 , since increased forces are required for this. The respective operational positions of the valve plate 9 are detected via the device 22 and passed on via a line 23 b to a signaling device 23 c .

The arrangement of the two-part piston 14 a , 14 b with the pilot control device 28 makes it possible to assign the control device 1 special response and closing characteristics. For example, it may be desired that, on the one hand, a pre-specified pressure must not be exceeded, on the other hand, however, a minimum pressure must also be present in the pressure vessel 17 . Such an operating behavior can be realized through the precise setting possibility of the pilot control device 28 and the spring 18 .

The control device 1 can be used in particular in pressure vessels of power plants or also nuclear reactors, in which the value is placed on safe and precise pressure maintenance.

Claims (8)

1. Control device ( 1 ) for a safety valve ( 4 ) of a pressure vessel ( 17 ) working according to the relief principle, in which the pressure vessel ( 17 ) is connected via a measuring line ( 16 ) to the piston chamber ( 15 ) of a piston ( 14 ) Valve plate ( 9 ) in a valve chamber ( 2 a ) is sprung on an opening ( 11 ) provided with a valve seat ( 8 ), one end connected to the control chamber ( 3 ) of the Sicherheitsven tiles ( 4 ), control line ( 2 ), one Ausblaselei device ( 5 ) and means for non-positive connection between the piston ( 14 ) and the valve plate ( 9 ) are provided, characterized in that the other end of the control line ( 2 ) is connected to the valve chamber ( 2 a ) and the blow-out line ( 5 is connected) outside of the valve chamber (2a) to the opening (11) on the valve seat (8). 2. Control device according to claim 1, characterized in that the piston ( 14 ) is under the pressure of a spring. 3. Control device according to claim 1 or 2, characterized in that as a means for the force-locking connection a piston ( 14 ) arranged piston rod ( 20 ) and / or on the valve plate ( 9 ) arranged plunger ( 10 b ) is used. 4. Control device according to claim 1, 2 or 3, characterized in that a ball joint ( 24 ) serves as means for the force-locking connection, the ball ( 24 a ) in a pan ( 24 b ) on the valve plate ( 9 ) and its Zap fen ( 24 c ) is designed as a piston rod or its ball ( 24 a ) in a pan ( 24 b ) on the piston ( 14 , 14 b ) and its pin fen ( 24 c ) are arranged on the valve plate ( 9 ). 5. Control device according to one of claims 1 to 4, characterized in that the piston ( 14 ) is assigned a further piston chamber ( 15 b ) which is connected via a channel ( 21 ) to the piston chamber ( 15 ). 6. Control device according to one of claims 3, 4 or 5, characterized in that the piston rod ( 25 ) and / or the pin ( 24 c ) are mounted in a bearing which is provided with a bellows seal ( 26 ). 7. Control device according to one of claims 1 to 6, characterized in that the piston ( 14 a , 14 b ) is designed as a stepped piston with a first ( 15 a) and a second ( 15 b) piston chamber and that the piston ( 14 a , 14 b ) associated piston chambers ( 15 a , 15 b ) are connected to one another via lines ( 27 a , 27 b ) and a pilot control device ( 28 ) arranged between them. 8. Control device according to one of claims 1 to 7, as by in that a means (22) for detecting the position of the valve disc (9) to the valve disc (9).