DE9320686U1 - Ring piston valve - Google Patents

Description

The invention relates to a ring piston valve with a rotationally symmetrical housing which is drawn inwards on the outlet side and is provided with a valve seat, a guide cylinder arranged concentrically in the housing and only open on the outlet side, a valve piston guided therein in a rotationally fixed and axially displaceable manner, which has a valve seal on its front side emerging from the guide cylinder, and a throttle element in the form of a perforated cylinder arranged in the annular gap between the housing and the valve piston.

Ring piston valves are used as pure throttle valves, as control or shut-off valves. Depending on the intended use, the valve seal itself or the outlet side of the valve is designed differently. The ring piston valve with perforated cylinder mentioned at the beginning is preferably used as a control device for large pressure differences and low back pressure,

e.g. at container inlets or similar. It is characterized by good control characteristics and by the fact that the pressure on the perforated cylinder is reduced largely without cavitation phenomena.

The invention is based on the object of proposing a ring piston valve of the initially mentioned design for larger pressure differences with simultaneously improved control characteristics.

This object is achieved according to the invention in that a further, concentric hole cylinder is provided at a distance from the hole cylinder, the through holes of which are arranged offset from those of the first hole cylinder.

With this design of the ring piston valve, a two-stage throttle is created in the annular gap between the valve piston and the valve seat, which allows higher inlet pressures to be effectively reduced or to be regulated against extremely low counter pressures.

5 In a preferred embodiment, the through holes of one perforated cylinder have a different cross-section than those of the other perforated cylinder. Advantageously, the cross-section of the through holes of the inner perforated cylinder is larger than that of the through holes of the outer perforated cylinder, so that a pressure reduction takes place within the throttle device from the inlet side to the outlet side. The cross-sectional shape of the through holes in the two perforated cylinders can also be different.

A further advantageous embodiment is characterized by the fact that the hole cylinders can be adjusted axially or rotationally to adjust the hole offset.

In this embodiment, the throttling effect of the ring piston valve can be easily adapted to the respective requirement (level of pressure difference or counterpressure) by adjusting the hole cylinders and thereby changing the degree of coverage of the through holes.

In a further preferred embodiment, it is provided that the perforated cylinders are connected at one end to the valve piston and - extending the latter - dip into the valve seat at their other end, and that the valve seal is arranged on the valve piston outside the outer perforated cylinder.

The outside diameter of the outer perforated cylinder is slightly smaller than the inside diameter of the ring-shaped valve seat, so that the perforated cylinder is more or less immersed in the valve seal when the valve is operated and a correspondingly smaller or larger axial length of the perforated cylinder within the annular gap between the housing and the piston acts as a throttle. The valve seal on the ring piston, as well as the valve seat, are located on the high-pressure side in front of the perforated cylinders, so that they are not exposed to cavitation.

0 Further details and advantages of the invention emerge from the following description of the embodiments shown in the drawings. In the drawing:

Figure 1 shows an axial section of the ring piston valve, whereby the perforated cylinders are not shown for reasons of clarity;

Figure 2 shows an enlarged partial section of a first embodiment of the ring piston valve according to Figure 1

and

Figure 3 shows a section corresponding to Figure 2 of a second embodiment of the ring piston valve.

The ring piston valve has a rotationally symmetrical housing 1, which is drawn inwards on both of its front sides and is inserted into a fluid line in which a liquid or a gas flows in the direction of arrow 2. On the outlet-side front side, the housing 1 has a valve seat 3, which is preferably made of a metallic material.

A guide cylinder 4 is arranged concentrically within the housing 11, which is closed on its inlet-side front side 5 by a spherical surface, but is open on the opposite, outlet-side front side. The valve piston 6 is again arranged concentrically within the guide cylinder 4, which reaches through the open front side of the guide cylinder 4 with one of its front sides 7 and has an annular valve seal 8 there. The valve piston 6 is guided axially displaceably and non-rotatably on webs 9 of the guide cylinder 4. In the area of its front side 7, the valve piston 6 is sealed on the guide cylinder 4 by means of ring seals 10.

The valve piston 6 is driven manually or by motor by means of a shaft 11 that passes through the housing 1. The torque of the shaft 11 is transmitted via a

Crank drive, consisting of the crank 12, the connecting rod bearing 13, and the connecting rod 14, is converted into a linear movement of the valve piston. The valve piston can thus be moved from the guide cylinder 4 in the direction of the valve seat 3 from the open position according to Figure 1 into the closed position (not shown), in which the valve seal 8 rests on the valve seat 3.

The ring piston valve according to Figure 1 can be used as a shut-off device, as a control device or simply as a throttling device.

The perforated cylinders 15, 16, which are not shown in Figure 1 for reasons of clarity but can be seen in more detail in Figures 2 and 3, are provided as a control device for large pressure differences and low back pressure on the outlet side. The perforated cylinders 15, 16 are arranged coaxially. The outer perforated cylinder 15 has through holes 17, the inner cylinder 16 has through holes 18, which are evenly distributed around the circumference. The through holes 17 of the outer perforated cylinder 15 have a smaller diameter than the through holes 18 of the inner perforated cylinder 16. Furthermore, the through holes 17, 18 in the two perforated cylinders are offset from one another. Finally, the perforated cylinders 15, 16 are a short distance apart from one another, so that a gap 19 is formed between them. The flow is throttled by the perforated cylinders and the high pressure on the inlet side is reduced to the lower back pressure on the outlet side. The pressure difference or counterpressure can be regulated by means of the valve piston 5.

In the embodiment according to Figure 2, the perforated cylinders 15, 16 are fixed to the valve seat 3 and the valve piston 5 is immersed in the inner perforated cylinder 16 when axially adjusted and covers a different number of through holes 18 on the inner perforated cylinder 16 depending on the immersion depth. In the closed position, the valve seal 8 located inside the inner perforated cylinder 16 on the valve piston 5 seals against the valve seat 3.

In the embodiment according to Figure 3, the perforated cylinders 15, 16 are attached to the leading end face of the valve piston 5 and the valve seal 8 is located outside the outer perforated cylinder 15. The outer perforated cylinder 15 has a diameter that is slightly smaller than the inner diameter of the valve seat 3, so that the perforated cylinders 15, 16 are immersed in the valve seat 3 when the ring piston 5 is axially adjusted. Depending on the immersion depth, a greater or lesser number of the through holes 17 of the outer perforated cylinder 15 are closed. In the end position - the closed position of the ring piston valve - the valve seal 8 lies sealingly against the valve seat 3. This embodiment has the advantage that the valve seal 8 is protected from possible cavitation, which can occur due to the throttling at high pressure differences or with corresponding media.

In order to increase the control range, the hole cylinders 15, 16 can be adjusted relative to each other. This can be achieved most easily by making one of the two hole cylinders rotatable relative to the other. In the embodiment according to Figure 3, this can be done, for example,

This can be done in the simplest way by having one perforated cylinder 15 rigidly connected to the valve piston 5, while the other is rotatably mounted on the valve piston and both perforated cylinders 15, 16 are connected via a self-locking thread or the like.

The through holes 17, 18 in the perforated cylinders 15, 16 can have any cross-sectional shape, possibly even different ones. They can be designed as round, square or elongated holes, for example. The perforated cylinders can be made from a tube or a perforated sheet.

Claims (6)

PATENT ATTORNEY..· ·„· „· ..· · DIPL.-I . HEINER LICHTI DlPL-PHYS. DR. RER. NAT. JOST LEMPERT D-76207 KARLSRUHE (DURLACH) PO BOX 410760
DIPL-ING. HARTMUT LASCH PHONE: (O72D94328I5 FAX: (07211 9432B40 Bopp & Reuther 12806.3/94 Lj/kr Armaturen GmbH ²⁸ · September 1994 Carl-Reuther-Str. 1 68305 Mannheim Protection claims 1. Ring piston valve with a rotationally symmetrical Housing which is drawn inwards on the outlet side and provided with a valve seat, a guide cylinder arranged concentrically in the housing and only open on the outlet side, a rotationally fixed and axially
slidably guided valve piston, which has a valve seal on its front side emerging from the guide cylinder, and a valve seal arranged in the annular gap between the housing and the valve piston. Throttle body in the form of a perforated cylinder
characterized in that a further, concentric perforated cylinder (16) is provided at a distance from the perforated cylinder (15), the through holes (18) of which are offset from those (17) of the first. 2. Ring piston valve according to claim 1, characterized in that the through holes (17, 18) in the two hole cylinders (15, 16) have different cross sections. 3. Ring piston valve according to one of claims 1 or 2, characterized in that the through holes (18) of the inner perforated cylinder (16) have a larger cross section than those (17) of the outer perforated cylinder (15). 4. Ring piston valve according to one of claims 1-3, characterized in that the through holes (17) of one hole cylinder (15) have a different cross-sectional shape than that of the other hole cylinder (16). 5. Annular piston valve according to one of claims 1-4, characterized in that the hole cylinders (15, 16) are axially or rotationally adjustable relative to one another to adjust the hole offset. 6. Ring piston valve according to one of claims 1-5, characterized in that the perforated cylinders (15, 16) are connected at one end to the valve piston (5) and - extending the latter - dip at their other end into the valve seat (3), and that the valve seal (8) is arranged outside the outer perforated cylinder (15) on the valve piston (5).