EP0740083A2 - Pressure cut-off valve with a shuttle valve piston - Google Patents

Abstract

The valve (1) has a changeover piston (2b) which can slide between two end positions in a bore (3) under the action of the higher of the pressures in two pipes (A,B). The higher pressure is limited by a piston (5), when the changeover piston is in either end position. The changeover piston also makes a connection (6) in either of its end positions between the pipe with the lower pressure and at least one opening (7) for flushing out the working medium. It may have a seal (9) which seals the higher of the pressures from this opening. The connection may be made through a longitudinal section (8) of the piston which has a dia. which is less than that of the bore, and it may also have axial grooves (11).

Description

The present invention relates to a pressure cut-off valve according to the preamble of the appended patent claim 1.

Such a commercially available pressure cut-off valve is known from the applicant's catalog sheet RDE 92002-6.2.1 - L + B / 10.89 and is shown in FIG. 3 of the accompanying drawings. The pressure cut-off valve 1 shown in FIG. 3 has a shuttle valve piston 2a, which is slidably arranged in a bore 3 of the pressure cut-off valve 1. By applying the higher pressure of a working medium in one of two lines A, B, the z. B. can be formed by lines of the high and low pressure side of an axial piston machine or the like, the shuttle valve piston 2a is displaceable between two end positions. The shuttle valve piston 2a has an inner bore 4 which extends over its entire length and through which at least in one of the two end positions a measuring piston 5 for pressure cut-off (pressure limitation) is subjected to the higher pressure. Despite or precisely because of its very simple and space-saving design, this pressure cut-off valve known from the prior art has no possibility of continuously flushing out a certain amount of working medium from the line having the respectively lower pressure in order to e.g. to supply cooling and / or cleaning.

A shuttle valve is known from DE 35 26 581-C2, the piston of which can be displaced between two end positions in one of two lines (6, 7) by fogging with the higher pressure of a working medium. This shuttle valve also has no possibility of continuously flushing out a certain amount of working medium from the line having the lower pressure.

Furthermore, from DE 41 18 244-A1 pressure relief valves (1, 2) are known, the pistons of which, however, are not designed as shuttle valve pistons, which can be displaced in one of two lines by exposure to the respectively higher pressure of a working medium.

The present invention is therefore based on the object of providing a pressure cut-off valve according to the preamble of the appended patent claim 1, which permits continuous flushing out of the working medium from a line having a respectively lower pressure.

This object is achieved according to the appended claim 1 by a pressure cut-off valve with a shuttle valve piston, which is arranged in a bore in the pressure cut-off valve in a sliding manner and can be displaced in one of two lines between two end positions by the application of the higher pressure of a working medium, the shuttle valve piston optionally being one extending over its entire length has an inner bore through which a measuring piston for pressure cutoff is acted upon by the higher pressure in at least one of the two end positions of the shuttle valve piston, and which is characterized in that the shuttle valve piston is designed so that a connection between the two end positions only the line with the lower pressure and at least one flushing opening for flushing out the working medium is released.

Advantageous developments of the present invention are specified in the subclaims.

The main advantage of the pressure cut-off valve according to the present invention lies in the simple, space-saving and very inexpensive design. Another great advantage is that the shuttle valve piston forming an essential part of the present invention can be integrated into the bore of the above-mentioned commercially available pressure cut-off valve.

Fig. 1

den Querschnitt eines erfindungsgemäßen Druckabschneidungsventiles,

Fig. 2

eine Vergrößerung des unteren Teiles der Fig. 1, und

Fig. 3

den Querschnitt eines handelsüblichen Druckabschneidungsventiles.

The present invention is explained in more detail below on the basis of a preferred exemplary embodiment with reference to the accompanying drawings, in which:

Fig. 1

the cross section of a pressure cut-off valve according to the invention,

Fig. 2

an enlargement of the lower part of Fig. 1, and

Fig. 3

the cross section of a commercially available pressure cut-off valve.

1 and 2 show a pressure cut-off valve 1 with a shuttle valve piston 2b. The shuttle valve piston 2b is slidably arranged in a bore 3 of the pressure cut-off valve 1 and is acted upon by the respectively higher pressure of a working medium supplied through the lines A and B. The two lines A and B can z. B. the high and low pressure lines of a hydrostatic engine or the like. Z. B. a greater pressure in line B than in line A, the shuttle valve piston 2b, as shown in FIGS. 1 and 2, is displaced into a lower end position by the higher pressure acting on its upper end. He sits with its lower end on an end cap 16. If the shuttle valve piston 2b, as shown, is in its lower end position, the working medium from line B with the higher pressure acts directly on a measuring piston 5 located at the corresponding end of the bore 3 of the pressure cutoff valve 1 for pressure cutoff. In the case shown in FIGS. 1 and 2, the measuring piston 5 is arranged in the extension of the longitudinal axis of the bore 3 and the shuttle valve piston 2b in a bore adjoining the bore 3 for receiving the measuring piston 5. The working medium enters line B through an inlet opening 12 located laterally on the bore 3 into the upper end of the bore 3 in FIGS. 1 and 2. At the same end of the bore 3 there is the corresponding outlet opening 13 for the working medium supplied through the line B directly opposite the inlet opening 12. Through an inner bore 4 extending over the entire length of the shuttle valve piston 2b, the higher pressure working medium of line B is led to the end cap 16, which has a bore 17 through which the higher pressure working medium can be supplied with additional functions.

In the event that line A has a higher pressure than line B, the above applies in an analogous manner because of the fully symmetrical design. Accordingly, the shuttle valve piston 2b is then moved upward and the working medium having the higher pressure is passed from line A through the inner bore 4 of the shuttle valve piston 2b to the measuring piston 5 for pressure cutoff.

The measuring piston 5 for pressure cut-off works in a known manner. At a certain set high pressure value, a spring pushing down the measuring piston 5 is compressed, and the working medium under pressure is discharged via the control edge (5.2) of the control piston (5.1).

The following explanations are made on the assumption that line B carries a higher pressure working medium than line A, so that the shuttle valve piston 2b is displaced into its lower end position, as shown in FIGS. 1 and 2. However, the following statements apply analogously to the reverse case.

The working medium of line B, which is under a higher pressure, pushes the shuttle valve piston 2b into its lower end position. As a result, due to the special structural design of the shuttle valve piston, a connection to one or two flushing orifices 7 is released to the working medium coming from line A through inlet port 14 onto the shuttle valve piston at a lower pressure. In the exemplary embodiment shown, the flushing opening is located between the inlet openings 12 and 14 in the pressure cutoff valve 1 and leads to a flushing line 18. The pressure cutoff valve 1 can also have a further flushing opening 7 in its opposite wall. The flushing line 18 leads to a tank in which the flushed-out working medium is cleaned and cooled, or to the housing of a hydrostatic engine, where the working medium is used to lubricate the engine, the pump or the like.

In the wall of the pressure cutoff valve 1 opposite the inlet opening 14 there is an outlet opening 15 for the working medium of the line A.

The shuttle valve piston 2b has at its upper and at its lower end sealing elements or sections 9 which have the same cross-sectional area as the bore 3 of the pressure cut-off valve. In this way, in the lower end position of the shuttle valve piston shown in FIGS. 1 and 2, the upper sealing element 9 seals the high-pressure side, which is formed by the line B, the inlet and outlet openings 12 and 13 and the upper end of the bore, from the low pressure side in which the rinsing of the working medium from line A to the rinsing opening 7 takes place. The lower sealing element 9 of the shuttle valve piston 2b is arranged thereon or has such a width that the working medium arriving from the line A through the inlet opening 14 finds a passage between the inner edge of the lower sealing element 9 and the outer edge of the inlet opening 14 which it can reach the flush opening 7. The lower sealing element 9 does not close the outlet opening, so that Working medium can continue to flow from the inlet opening 14 to the outlet opening 15.

Between the two sealing elements 9 located at its outer ends, the shuttle valve piston 2b is designed such that the working medium entering between the sealing element 9 and the inlet opening 14 can reach the flushing opening 7. For this purpose, the shuttle valve piston between the two sealing elements 9 consists of several sections 8, the cross-sectional area of which is smaller than the cross-sectional area of the bore 3 of the pressure cut-off valve 1. In the case of a cylindrical shuttle valve piston 2b and a cylindrical bore 3, this means that the sections 8 have a smaller diameter than the bore 3. Three such sections 8 are shown in FIGS. 1 and 2. Cavities are thus formed between the outer surfaces of these sections 8 and the inner wall of the bore 3, which create the connection 6 between the low-pressure line A and the flushing opening 7.

Between the sections 8, the shuttle valve piston has throttle elements 10, by means of which the amount of the working medium flushed out is limited. In FIGS. 1 and 2, these throttle elements 10 are formed by throttle sections, the cross-sectional area of which is smaller than the cross-sectional area of the bore 3 but larger than the cross-sectional area of the sections 8. The flushed out working medium thus finds smaller passage openings at the location of these throttle sections, and is throttled. In the case of a cylindrical shuttle valve piston 2b and a cylindrical bore 3, the throttle sections have a diameter which lies between the diameter of the sections 8 and the diameter of the bore 3.

In a preferred exemplary embodiment, the throttle sections have one or more axial or longitudinal grooves 11, by means of which the flow of the flushed-out working medium between the line A and the flushing opening 7 is limited.

The shuttle valve piston 2b is preferably of symmetrical design, so that the function according to the invention is given even when the flow direction of the working medium is reversed or the high and low pressure sides are interchanged.

Furthermore, it is basically conceivable for the throttle sections in the section of the bore 3 between the openings 12, 13 and 14, 15 by means of grooves in the bore wall to achieve, but the function of the respective sealing element 9 must be ensured.

Claims (7)

Pressure cut-off valve (1) with a shuttle valve piston (2b), which is slidably arranged in a bore (3) of the pressure cut-off valve (1) and can be moved between two end positions in one of two lines (A, B) by applying the higher pressure of a working medium , wherein the shuttle valve piston (2b) optionally has an inner bore (4) extending over its entire length, through which a measuring piston (5) for pressure cutoff is acted upon by the higher pressure in at least one of the two end positions of the shuttle valve piston (2b),
characterized in that
the shuttle valve piston (2b) is designed so that in both end positions a connection (6) between only the line (A or B) with the respective lower pressure and at least one flushing opening (7) for flushing out the working medium is released. Pressure cut-off valve according to claim 1,
characterized in that
the shuttle valve piston (2b) has at least one end a sealing element (9) which, in the corresponding end position, forms a seal between the line (A or B) with the higher pressure and the at least one flushing opening (7). Pressure cut-off valve according to claim 1 or 2,
characterized in that
the shuttle valve piston (2b) has sections (8) in the longitudinal direction, the cross-sectional area of which is smaller than the cross-sectional area of the bore (3) of the pressure cut-off valve (1) and which thus form the connection (6) for flushing out the working medium. Pressure cut-off valve according to claim 3,
characterized in that
throttle elements (10) are provided between the sections (8), which limit the amount of flushed working medium. Pressure cut-off valve according to claim 4,
characterized in that
the throttle elements (10) are formed by throttle sections, the cross-sectional area of which is larger than that of the sections (8) and smaller than that of the bore (3). Pressure cut-off valve according to claim 5,
characterized in that
the throttle sections have axial grooves (11). Pressure cut-off valve according to one of the preceding claims,
marked by
a symmetrical design of the shuttle valve piston (2b) with an inner bore (4) such that either one of the lines A or B is the one with the higher pressure.

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