DD226341B1 - VALVE - Google Patents

Abstract

Valve for installation in hydraulic circuits containing aggressive media, preferably for small flow rates in medical and laboratory equipment. The valve is optimally adaptable in its proportions according to the field of application with low flow rates and has a relatively low production cost. In a valve housing, a structurally homogeneous valve body is arranged under prestress. The valve body consists of a valve closure member and a support member with flow channel, which are connected to each other via elastic webs.

Description

The invention relates to a valve for installation in hydraulic circuits in which are aggressive media, preferably for small flow rates in medical and laboratory equipment.

It has been proposed a solution in which a valve housing has a bushing with a sealing surface on which the sealing body z. B. in the form of a ball, wherein the sealing body is pressed by a spring element in the form of a non-metallic elastic ring.

On a cover, which is placed on the socket, there are webs for holding the spring element (DD-Acc. F16 K /

This solution is not suitable for use in hydraulic circuits with low flow rates of aggressive media for optimum dimensioning of the valve size, since the required dimensional reduction of the valve elements, the production is feasible only under complicated technological conditions.

The aim of the invention is to provide a valve which is optimally adaptable in its proportions to the field of application with low flow rates and has a relatively low production cost.

The invention has the object to reduce the number of valve elements and to simplify their structural design.

According to the invention the object is achieved by a valve closure member is located in a valve housing with a recess which is pressed by means of a resilient element in the form of elastic webs against the valve seat.

The elastic webs are also connected to a support member containing a flow channel.

The valve closure member, the webs and the support member form a structurally homogeneous valve body which is arranged under prestress in the valve housing.

In the flow direction of the medium, the valve closure member is lifted from the valve seat when the pressure of the medium is greater than the force of the bias voltage. The thereby flowing into the valve housing medium passes through the existing between the elastic webs openings in the flow channel of the support element and flows into the hydraulic system.

In a reversal of the pressure conditions in the medium, the valve closure member is pressed against the valve seat and blocks the flow direction.

The desired bias of the valve body results from the dimensioning of its axial length and the dimensions and number of resilient webs in dependence of the elastic material used.

The solution according to the invention provides the advantage that valve closure part, the webs and the support element consist of a structurally homogeneous body of the same elastic material and thereby valves in small dimensions and precise dosing are inexpensive to produce.

The invention will be explained in more detail below by exemplary embodiments.

In the accompanying drawings show

Fig. 1: The valve shown in section.

Fig. 2: The use of the valve in the hydraulic circuit of a diaphragm pump, partially shown in section.

Fig. 3: The design of the valve used as a check valve in a line, shown in section.

According to Fig. 1, the valve housing 7 consists of two bushings 7.1, 2.7, which are provided with their opposite faces e.g. connected by gluing together. While one bushing 7.1 represents the valve seat 13 in the form of a truncated cone, a bore 14 is arranged opposite in the other bushing. In the valve housing 7 is a vulcanized from an elastic material valve body 15, which consists of a valve closure part 15.1, which is connected by means of elastic webs 16 with a support member 15.2 exists. The material of the valve body 15 is adapted to the flow medium. While the valve closure member 15.1 rests with its free end, which is hemispherical in shape, on the conical valve seat 13 of the bushing 7.1, the cylindrically shaped free end of the support element 15.2 projects into the bore 14 of the bushing 7.2 and is supported on the support surface 24 of the plate 8 from, which is arranged over the sleeve 7.2. According to the selected in the vertical direction excess of the valve body 15 to the valve housing 7, the valve body 15 is arranged with bias in the valve housing 7.

To the longitudinal axis, the valve body 15 has a flow channel 18 which penetrates the support member 15.2 and continues in the valve closure member 15.1 as a recess.

The gap 17 between the elastic webs 16 is formed as a flow opening for the medium and is in communication with the flow channel 18. The bushing 7.1 has centrally an opening 19 through which the medium flows into the valve and flows through the intermediate space 17, the flow channel 18, through which is located in the plate 8 opening 20 and the connecting element 9 in the further hydraulic system.

The webs 16 simultaneously represent the spring element required for the valve function and are dimensioned as a function of the force necessary for the valve function force of the bias of the valve body. The bushes have 7.1.7.2 on the opposite sides circumferential grooves 11,12 in which sealing elements 10 are in the form of round rings, which ensure the tightness of the arrangement to the outside.

2, the membrane 1 of a diaphragm pump to the sealing surface 2 of the valve seat 3 is pressed firmly. The valve seat 3 has a displacement 4 and further chambers 5 for receiving the valve housing 7.

The displacement 4 is connected via the connecting channel 6 with the chambers 5. The valve housing 7 are held in the chambers 5 by means of a respective plate 8, the hydraulic connection elements 9.

To seal the liquid-carrying sections sealing elements 10 are arranged in the chambers 5.

According to Fig. 3, the valve housing 7 consists of two identically shaped sockets 7.3 and 7.4, on which axial connection elements 22 are arranged. Both bushings 7.3 and 7.4 each have a geometrically identical conical surface as a valve seat 13 or support surface 25. In the connection elements 22 of the sockets 7.3 and 7.4 are channels 21 which are connected to the line system. The valve body 23 located in the valve body 23 consists of a valve closure part 23.1 and support member 23.2, which are connected to each other by means of elastic webs 16.

The free ends of the valve closure part 23.1 or support element 23.2 are designed hemispherical and are based on the conical valve seat 13 and on the support surface 25 from. To the longitudinal axis of the valve body 23 has a flow channel 18 which penetrates the support member 23.2 and extends into the valve closure member 23.1.

The flow channel 18 communicates with the space 17 formed as a flow passage for the medium. In the flow direction, the sealing element is 23.1 lifted off the valve seat 13, and thus ensures the flow of the medium through the gap 17 and flow channel 18 in the line system, depending on the existing pressure conditions.

In the blocking direction, depending on the existing pressure conditions, the support element 23.2 is pressed with its hemispherical end against the valve seat 13, thus preventing a reversal of the flow direction of the medium.

Claims (2)

Valve, preferably for small flow rates, in which there is a valve closure member in a valve housing with a recess which is pressed by a resilient member against the valve seat, characterized in that the resilient element in the form of elastic webs (16) is formed, which also are connected to a support element (15.2,23.2), wherein the support element (15.2,23.2) includes a flow channel (18), and that the valve closure part (15.1, 23.1), the webs (16) and the support element (15.2, 23.2) a constructively homogeneous valve body (15, 23) form, which is arranged under prestress in the valve housing (7). For this 2 pages drawings