CS261615B1 - Control valve for gaseous or liquid pressure medium - Google Patents

Abstract

The proposed device creates a control valve controlled by the energy of its own pressure medium, which eliminates the leakage of known designs. The secured pressure space is connected via the inlet space to the internal space between the smaller bellows and the larger bellows and is at the same time separated from the internal space of the smaller bellows by a seat and a cone, while the internal space of the smaller bellows is connected via an exhaust pipe via a throttle diaphragm to the exhaust and at the same time via an impulse pipe to the working space of the controlled device.

Description

The present invention provides a control valve for a gaseous or liquid pressure environment operating as a discontinuous direct pressure regulator. It is used to control various devices, especially valves, such as controlled safety valves, bypass valves, quick-acting valves.

Pressure regulators are known for this purpose based on the principle of rectifying or interrupting the flow of liquid or gaseous medium flowing out of the nozzle, the so-called "pressure tuning". These controllers have relatively good performance characteristics. Their reliability is largely dependent on the cleanliness of the working medium. Therefore, in most cases, the actual regulated pressure medium cannot be used to control the controller, but a foreign pressure medium must be used. If a foreign pressure medium is not available, a source must be set up. Reliability is then dependent on the delivery of this pressure medium. In addition, the foreign pressure medium constantly escapes through the nozzle, which in many cases leads to very negligible energy losses. The closeness of function to these controllers is achieved by their high sensitivity, which is limited by the stability of the controller. However, under slow pressure changes in the pressure chamber, the function of the regulator may be continuous, leading to undesired intermediate positions of the controlled control. Control valves are usually used to control controlled relief valves. Some are controlled by the energy of the pressure medium itself. They are basically direct-acting safety valves of small diameters. Their disadvantage is low tightness, inaccuracy of function, relatively low adjusting forces and sliding guide surfaces, which can lead to failure of operation. The second group of control valves are solenoid or electric actuated valves. They have good tightness and accuracy of function. Reliability, however, depends on the source and power supply.

These disadvantages are eliminated by the control valve for the pressure environment gaseous or liquid, when the pressure in the protected pressure space rises above the set value, the sudden opening and acting pressure increase in at least one closed working space of the controlled device and when the pressure in the protected pressure space drops The pressure reduction in the working space of the controlled device according to the invention is suddenly closed and acting again.

SUMMARY OF THE INVENTION The fused pressure chamber is connected to the inner space between the smaller bellows and the larger bellows via the inlet space in the body, and at the same time is separated from the inner space of the smaller bellows by the seat and plug. orifice with the exhaust and at the same time impulse piping and working space of the controlled device.

The body on which the flange is located is rigidly connected by means of two long connecting rods provided with the first spacer rings and first nuts to the flexible annular plate, while the flexible annular plate is rigidly connected by two short connecting rods provided with short spacer tubes, second, spacer rings and the second nuts and the lower nuts with the top plate, the plane passing through the longitudinal axes of the two long tie rods is parallel to the plane passing through the longitudinal axes of the short tie rods. The cone is connected to a ball pin on which the lower ring and the lower washer are located, the inner periphery of the smaller diaphragm being clamped between the lower ring and the lower washer, the outer periphery of the smaller diaphragm being clamped between the body and the spacer; wherein the outer periphery of the larger diaphragm is held between the lid and the spacer while the inner periphery of the larger diaphragm is clamped, between the washer and the upper ring and the upper washer and the upper ring are fixed to the upper rod connected to the ball pin. The throttle orifice is formed by an adjustable element, in particular a control valve.

The control valve according to the invention has the advantage of being controlled by the energy of the pressure medium itself and of high accuracy. It is possible to set both the pressure at which intervention is to take place, i.e. the opening pressure as well as the pressure at which the valve is to return to its original position, i.e. the closing pressure of the valve. It is also advantageous to seal the valve at a pressure already 5-10% lower than the opening pressure given by a sufficient sealing pressure between the plug and the valve seat.

An example of the invention is shown in the accompanying drawings, in which Fig. 1 is a broken sectional view of the control valve, and Fig. 2 is a plan view of the control valve and showing a broken section. Giant. 3 is a cross-sectional view of an alternative embodiment of a positive pulse control valve.

In the positive pulse control valve body 1 according to FIGS. 1 and 2, a supply space 2 is provided, which is connected via a supply line 3 to the pressure chamber 5. The body 1 is by means of long connecting rods 10, long spacer tubes 12, first spacer rings 14. and the first nuts 16 are rigidly connected to the crossbeam 8 so that these parts form a stationary unit with the body 1. The upper plate 6, the smaller bellows 20, the flange 7, the body 1 with the seat 25 and the cone 24 impermeably enclose the interior 22 of the smaller bellows 20. The upper plate 6, the smaller bellows 20, the larger bellows 19 and the flange 7 impermeably enclose the interior 21 between the smaller bellows The arrangement of the smaller bellows 20 and the larger bellows 19 is such that the smaller bellows 20 is located inside the larger bellows 19. The top plate 6 is by means of short connecting rods 11, short spacers tru261615 bek 13, second spacers 15, second spacers. of the nuts 17 and the lower nuts 18 connected to the reinforcement 9 such that these parts form a movable unit relative to the body 1. A cone 24 is mounted on the ball pin 23 provided on the top plate 6. Between the first spacer rings 14 and the first nuts 16 on the long connecting rods 10 and between the second spacer rings 15 and the short spacer tubes 13 on the short connecting rods 11 is clamped. The plane extending through the axes of the long tie rods 10 is parallel, preferably perpendicular, with the plane passing through the axes of the short tie rods III.

Thus, the resilient annular plate 26 together with the smaller bellows 20 and the larger bellows 10 form a link between the stationary assembly and the movable assembly allowing movement only in a direction perpendicular to the plane of the flexible annulus plate 26. This coupling thus forms the guide of the plug 24 to the seat 25 without passive resistance; seizures. The movable assembly is subjected to a force from the compression spring 23 by which the cone 24 is pushed into the seat 25. The reaction from the compression spring 29 is transmitted via the support plate 27 and the adjusting screw 28 to the crossbar 8. The adjusting screw 28 and the crossbar 8 have a threaded connection the bias of the compression spring 29. The inner space 21 between the smaller bellows 29 and the larger bellows 19 is connected by a channel 53 to the supply space 2 and thereby to the pressure chamber 5. The inner space 22 of the smaller bellows 20 separated by a seat 25 and a cone 24 from the supply space 2. it is connected to the exhaust pipe 32 via the throttle plate 4 and to the working space of the controlled device via the impulse pipe 31.

In an alternative embodiment of the shifting valve shown in Figure 3, the larger bellows 19 and the smaller bellows 20 of Figure 1 are replaced by the larger diaphragm 46 and the smaller diaphragm 47. This embodiment is simpler and applies where the larger diaphragm 46 and diaphragm 46 are used. the smaller diaphragm 47 will meet the requirements for the stroke of the plug 24 and the thermal and pressure loads.

The smaller diaphragm 47 is clamped by its outer periphery between the body 1 and the spacer 45. The larger diaphragm 46 is clamped by the outer periphery between the spacer 48 and the lid 49. The body 1, spacer 48 and the lid 49 are connected to each other by long connecting rods 10, top nuts 59 and lower nuts 51 so as to form a stationary assembly of the alternative embodiment. The smaller diaphragm 47 is clamped by its inner circumference with the upper rod 40 between the lower ring 40 and the lower washer 44 and the upper rod 40 is also connected to the inner periphery of the larger diaphragm 46 clamped between the upper ring 41 and the upper washer 43. the smaller diaphragms 47, the upper rod 40, the upper washer 43, the lower washer 44, the upper ring 41 and the lower ring 42 together with the thrust plate 45 and the cone 24 form one fixed assembly of an alternative embodiment. The body 1, the cone 24 with the seat 25 and the smaller diaphragm 47 enclose the inner space 53 of the smaller diaphragm 47. The spacer 48, the larger diaphragm 46 and the smaller diaphragm 47 impermeably enclose the internal space 52 between the larger diaphragm 46 and the smaller diaphragm 47. 1 and 2. The axial guidance of the movable assembly to the stationary assembly is provided by a larger diaphragm 46 and a smaller diaphragm 47. The interconnection of the respective spaces is the same as for the valve of FIGS. 1 and 2. .

The positive pulse control valve of FIGS. 1 and 2 operates as follows: if the pressure in the protected pressure space 5 is lower than the opening pressure of the valve to be actuated, the plug 24 is pushed into the seat 25 and the valve is therefore closed.

The pressure in the interior space 22 of the smaller bellows 34 as well as the pressure in the working space of the control device is equal to the pressure in the exhaust pipe 32, for example atmospheric pressure. In the inner space 21 between the smaller bellows 28 and the larger bellows 19 as in the inlet space 2, the pressure is equal to the pressure in the protected pressure space 5. The application of this pressure on the annular surface between the smaller bellows 20 and the larger bellows 19 When the pressure in the protected pressure space 5 reaches the opening pressure, the forces are equilibrated and the valve begins to release a small amount of pressure medium from the inlet space 2 into the interior space 22 of the smaller bellows 20, further via the exhaust pipe 32 through the throttle orifice 4 to the exhaust and the impulse pipe 31 into the working space of the controlled device. Assuming a closed working space of the controlled device, there will be an increase in pressure in this space and in the interior space 22 of the smaller bellows 20. This further increases the resultant force from the pressure. From the point of view of control circuit theory, it is about introducing positive feedback. From a certain small stroke of the plug 24 the force from the pressure increases as a function of its stroke at a constant pressure in the pressure chamber 5 more than the force from the compression spring 29, thereby opening the valve and finally increasing the pressure - positive impulse in the inner space 22 of the smaller bellows 20 and in the workspace of the controlled device. As the pressure in the pressure chamber 5 decreases, the pressure in the interior space 21 between the smaller bellows 20 and the larger bellows 19 decreases, the stroke of the plug 24 begins to decrease somewhat, thereby causing a steeper pressure drop in the interior space 22 of the smaller bellows 20.

261815

From a certain stroke and closing pressure in the pressure chamber 5, the resulting force decreases from the pressure more than the force from the compression spring 29 and the valve suddenly closes. The pressure in the space 22 of the smaller bellows 20 and in the working space of the controlled device decreases again to a pressure equal to the exhaust pressure. The throttle orifice 4 may also be formed by clearances in the working space of the controlled device.

By varying the throttling effects of the throttle orifice 4 and the cone 24 with the seat 25, the amount of pressure increase, i.e. the pressure pulse, and the difference between the opening and closing pressures are varied within a relatively wide range. The fixed throttle 4 can be replaced by an adjustable element, for example a control valve. The pressure pulse size can also be varied by including several throttle orifices 4 in the exhaust manifold 32 and connecting the pulse manifold 31 between the orifices at the desired pressure pulse level.

1 and 2 applies to the control valve of FIG. 3, with the interior 21 between the smaller bellows 20 and the larger bellows 19 and the interior 22 of the smaller bellows 20 being replaced by the interior 53 the smaller membrane 47 and the inner space 52 between the larger membrane 46 and the smaller membrane 47.

The area of the larger diaphragm 46 need not always be larger than the area of the smaller diaphragm 47, but the sum of the area of the larger diaphragm 46 and the plug 24 must be larger than the area of the smaller diaphragm 47 and the area of the smaller diaphragm 47 always larger.

Claims (4)

1. A control valve for a gaseous or liquid pressure environment, when the pressure in the protected pressure space rises above a specified value, a suddenly opening and acting pressure increase in at least one enclosed working space of the controlled device and when the pressure in the protected pressure space falls below a generally different value again a sudden closing and exerting pressure reduction in the working space of the controlled device, with a double pressure gauge, a plug, a seat and a spring, characterized in that the secured pressure space (5) is through the supply space ( 2) in the body (1) connected to the inner space (21) between the smaller bellows (20) and the larger bellows (19) and at the same time separated from the inner space (22) of the smaller bellows (20 by a seat (25 and a cone) the inner space (22) of the smaller bellows (20) is connected by the exhaust pipe (32) via the throttle (4) to the exhaust and at the same time by the impulse pipe (31) with the working space of the controlled device. . Control valve according to claim 1, characterized in that the body (1) on which the flange (7) is located is fixedly connected by means of two long connecting rods (10) provided with the first spacer rings (14) and first BACKGROUND OF THE INVENTION nuts (16) having a flexible annular plate (26), the flexible annular plate (26) being rigidly connected by means of two short connecting rods (11) provided with short spacers (13). the second spacer rings (15) and the second nuts (17) and the lower nuts (18) with the top plate (6), the plane passing through the longitudinal axes of the two long tie rods (10) is parallel to the plane passing through the longitudinal axes of the short tie rods (11j). Control valve according to claim 1, characterized in that the plug (24) is connected to a ball pin (23) on which the lower ring (42) and the lower washer (44) are located, between the lower ring (42) and the lower washer. (44) the inner periphery of the smaller diaphragm (47) is retained, the inner periphery of the larger diaphragm (46) being clamped between the upper washer (43) and the upper ring (41) and the upper washer (43) and the upper ring (41) fixed on the upper rod (40) connected to the ball pin (23). Control valve according to Claim 1, characterized in that the throttle plate (4) is formed by an adjustable element, in particular a control valve.