DE1253537B - Valve with a valve closure piece that opens and closes automatically due to the pressure of the medium - Google Patents

Description

Valve with a valve closure piece that opens and closes automatically due to the pressure of the medium. and with a connecting channel equipped with an adjustable throttle device between the inlet opening and the cylinder space closed off by the closure piece.

In this known valve, the valve closure piece used is constantly loaded in the closing direction by the force of a spring. The arrangement is such that the liquid pressure is automatically regulated each time a tap is opened which is located behind the valve, i. i.e., which is in the delivery line. This known valve is therefore a pressure regulator and not a flow regulator.

Furthermore, a valve for a water flush is known, which a Has shut-off delay. The amount of water dispensed depends on each actuation from the time an operating lever] is depressed. This too The valve has a locking piston which can move freely and in a sealed manner in a cylinder on and a connecting channel between the inlet opening and that of the sealing piston closed cylinder space, which represents a throttle point. As long as the lever is depressed, water flows through the valve. As soon as the lever is released is, the closing of the valve or the lowering of the sealing piston is thereby Delays that only slowly water through the throttle point or the connecting channel enters the interior of the cylinder. An actuation of this water flush valve is only possible by pressing the lever down.

Furthermore, a pressure reducing valve is known in which a piston after is pressed down when the feed pressure exceeds a certain value. Thereupon the feed pressure can also affect the underside of the piston§ and press this up again, as part of the upper piston circumference with the outside air communicates through a hole. Now lets the pressure in the outlet opening of the valve again, the piston is pushed down again, so that again Hydraulic fluid can flow in. The piston play repeats itself continuously, as long as the pressure at the outlet opening of the valve is lower than at the inlet opening. This known pressure reducing valve can therefore in no way be used as a metering valve.

- Finally, it is also known to use a screw thread as an adjustable throttle device, the length of the throttle section and thus the size of the throttling being changed by screwing the thread into a cylinder to a greater or lesser extent.

The object of the invention is to provide a valve of the type mentioned at the beginning Design to be designed so that the medium, especially air, in one direction unhindered, in the other, however, only during a limited, freely adjustable Time can flow through.

This object is achieved according to the invention in that the closure piece is designed as a differential piston, which interacts with the valve seat Seal at the transition point from the smaller to the larger part of the differential piston it is provided that the space of the cylinder which is closed off by the larger piston part is connected to the channel containing the throttle device and that the smaller one Piston part arranged so as to slide tightly in a cylinder connected to the outside air is.

On a spring loading the valve closure piece can in the case of the invention Valve can be dispensed with. It is therefore very low-wear and operationally reliable. The amount of medium flowing through is largely independent of the feed pressure, because the displacement of the valve closure piece in the closed position is practical takes place exclusively under the pressure of the medium penetrating into the cylinder space. If the medium is under low pressure, it takes a relatively long time to until pressure equalization takes place. On the other hand, at high pressure the Pressure equalization relatively quickly. The measured quantities are therefore essential regardless of the feed pressure that occurs.

The possible uses for the valve according to the invention are diverse. For example, it can be attached to one end of a compressed air cylinder in this way be connected so that its outlet opens into the outside air. Every time when the compressed air cylinder is then charged with compressed air again, it initially escapes the compressed air through the valve or the metering device for a certain period of time Free. The purpose of this is to actuate the piston of the compressed air cylinder to delay something that is desired in many applications of technology. Farther you can use the valve according to the invention to the gland seal a To put the piston-cylinder unit under pressure in order to completely close the sealing lips relieve and in this way reduce the friction of the piston rod or around the dirt wiping lip of lifting rams for throwing off the accumulated dirt take off.

The invention is illustrated below with reference to one in the drawing Embodiment explained in more detail, which is a vertical section through an inventive Metering device shows.

In the drawing, 1 denotes the tubular part of the metering device, in the ends of which plugs 2 and 3 are inserted, which have an inlet opening 4 and an outlet opening 5 and are provided with ring seals 20 and 21, respectively. A hole provided in part 1 is used to accommodate a closure piece 7, which can come to rest up against the surface of a transverse partition 8 of part 1 (position shown) and down to the contact of end 9 of its attachment 15 on surface 10 of the plug 3 can shift. The closure piece 7 is designed as a differential piston, the seal 14 of which cooperates with the valve seat 13 is provided at the transition point 12 from the smaller to the larger part of the differential piston. The shut-off can also be designed as a valve with a seat of the usual type or as a flat slide or the like.

C The differential piston is freely movable in its cylinder 6 and is sealed by means of an annular seal 11. The space 35 of the cylinder 6, which is closed off by the larger piston part, is connected to a channel 33, 34, 36, 37 containing a throttle device 27 to 32 . Furthermore, the smaller piston part forming the extension 15 is arranged so as to slide tightly in a cylinder 16 connected to the outside air. This smaller piston part also has an annular seal, which is denoted by 17. The connection with the outside air takes place by means of an opening 18 leading into the space 19 of the cylinder 16 below the extension 15.

In the exemplary embodiment shown, the cylinder space 35 is connected to the inlet opening 4 via a check valve 39 . This check valve closes channels 38 provided in the transverse partition 8 , which are shown in dashed lines in the drawing, and allows air to pass through only from bottom to top.

The housing of the metering device consists of two cylindrical parts screwed together, in which the plug 2 with the inlet opening 4 having part 1 the transverse partition 8 for receiving the throttle device 27 to 32 with the required connecting channels 33, 34, 36, 37 and the cylinder 6 for the larger part of the differential piston 7 and in its outlet opening 5 having, formed as a plug part 3 of the valve seat 13 and the cylinder 16 for the smaller part 15 of the differential piston formed as a shoulder and that both'Gehäuseteile of several axially parallel, the centrally arranged Flow channels 22 and 25 surrounding cavities are penetrated. These flow channels connect a chamber 23, which adjoins the inlet opening 4, with spaces 24 and 26, which surround the differential piston, and these in turn with the outlet opening 5.

The throttle device is designed as follows: Between the inlet opening 4 and the differential piston 7 , two coaxial outer bores 27, 28 are provided in the transverse partition 8 , which serve to accommodate a screw 29 which can move in these bores with the aid of its thread 30 . The threaded head is denoted by 31 and can be fixed by means of a lock nut 32. The end of the screw 29 enters the transverse bore 27 without play and has a helical groove 291 with a small cross section, which represents the throttle section. An annular groove 33 provided in the screw 29 connects the helical groove 291 to a bore 34 in the transverse partition 8 which opens out above the cylinder space 35. The end of the screw 29 is formed with a conical part 2922 opposite an inlet 36 for air to enter the helical groove 291 . A bore 37 connects this inlet 36 with the chamber 23.

The mode of operation is as follows: If the metering device is not supplied with compressed air, its inlet opening 4 is connected to the outside air. The differential piston 7 is in its lower position, so that the transition point 12 closes the passage from the space 24 to the space 26. If compressed air is now supplied, it enters the chamber 23 and through the flow channels 22 into the chamber 24. The further path is closed by the seal 14. At this moment, the pressure in the chamber 24 below the piston 7 exerts a force that lifts it. The size of this force is equal to the difference between the cross sections with the two diameters AB of the piston 7 and CD of the transition point 12 multiplied by the pressure. The cylinder space 35 above the piston 7 is still under the external pressure at this time, since it was previously, as will be described, in contact with the external air. The air located within the cylinder space 35 can be easily compressed, since it is only under the external pressure, so that practically no counterforce acts on the piston 7 and this jerks upwards. Here, the air in the cylinder space 35 is compressed. If the piston 7 is in its upper position, the transition point 12 releases the passage to the chamber 26 , so that the compressed air entering at the inlet opening 4 can flow through the metering device and exits at the outlet opening 5 .

The compressed air entering the chamber 23 through the inlet opening 4 also enters the inlet 36 through the bore 37 and flows through the narrow helical groove 291 of the screw 29. Via the annular groove 33 , this compressed air passes through the bore 34 into the above the piston Cylinder space 35. The helical groove 291 , however, opposes the passage of air with considerable resistance, which can be regulated by screwing the screw 29 into the bore 27 to a greater or lesser extent. Depending on the size of this resistance, it takes a more or less long time until the pressure prevailing in the space 23 also comes into effect in the cylinder space 35. When the full pressure also has an effect in the cylinder space 35 , the piston 7 is pressed downwards. The pressure prevailing in the space 35 acts on the full diameter AB of the piston, while the pressure acting on the same from below acts only on a cross-section with the diameter AB, which is reduced by the cross-section of the projection 15 with the diameter EF. Since the space 19 in which the extension 15 is displaced is in communication with the outside air through the bore 18 , only the external pressure acts on the extension 15. The air in the space 19 can be displaced easily through the bore 18. When the full pressure is reached in the space 35 , the control piston 7 goes down and closes the further supply to the outlet opening 5 by means of its transition point 12 and the seal 14.

If the metering device is then connected to the outside air via the inlet opening 4 after the compressed air has been switched off, the air in the space 23, the channels 22 and the space 24 can initially relax. The air contained in the cylinder space 35 can then, on the one hand, escape through the helical channel 291 and the bore 37 into the chamber 23 and, on the other hand, if the check valve 39 is provided, through the channels 38 also into the space 23 Metering device in its initial position again, the space 35 being under the pressure of the outside air.

The screw 29 can be used to set the throttling effect of the helical channel 291 and thus the time that is required until the full pressure takes effect in the space 35. However, the amount of air flowing through the metering device is also determined by the time it takes the control piston from its opening to its closing. By turning the screw 29 you can regulate the amount of air metered.

Claims (3)

Claims: 1. Valve with a piston-shaped valve closure piece, in particular a metering device for compressed air devices, which is equipped with an adjustable throttle device, and which is equipped with an adjustable throttle device between the inlet opening and the one closed off by the closure piece, which opens and closes automatically in a cylinder Cylinder space, characterized in that the closure piece (7) is designed as a differential piston, the seal (14) of which cooperating with the valve seat (13 ) is provided at the transition point from the smaller to the larger part of the differential piston, so that the space (35 ) of the cylinder (6) is connected to the channel (33, 34, 36, 37 ) containing the throttle device (27 to 32) and that the smaller piston part (15) slides tightly in a cylinder (16) connected to the outside air is arranged. 2. Valve according to claim 1, characterized in that the cylinder space (35) is connected to the inlet opening (4) via a check valve (39). 3. Valve according to claim 1 and 2, characterized in that the housing consists of two cylindrical parts screwed together, in which the inlet opening (4) having part (1) has a transverse partition (8) for receiving the throttle device (27 to 32) the necessary connecting channels (33, 34, 36, 37) and the cylinder (6) for the larger part of the differential piston (7) and in its part (3) having the outlet opening (5 ) the valve seat (13) and the cylinder (16) ) are provided for the smaller part (15) of the differential piston and that both housing parts are penetrated by several axially parallel flow channels (22, 25) surrounding the centrally arranged cavities. Documents considered: German Patent No. 116 067; German utility model No. 1789 444; French additional patent specification No. 17 276, addition to French patent specification No. 441 581; USA. Pat. No. 2,656,144.