DE936130C - Device for pressure-dependent control of a hydraulic system - Google Patents

Description

Device for pressure-dependent control of a hydraulic system The invention relates to a device for the pressure-dependent control of a hydraulic System in which the interior of a pressure cylinder is replaced by a differential piston is divided into two unequal sized rooms, in such a way that one room is a larger one has effective piston area than the other. The smaller cylinder space with the The smaller fecal area is under hydraulic pressure, and the larger one with the larger piston area has a drainage facility for the hydraulic fluid, so the piston can be moved in the direction of the larger cylinder space. If the If the piston is to hit the opposite direction, the larger cylinder space will be the pressure line that transports the hydraulic fluid. Pump connected, so d @ ate the Pressure in the larger cylinder space. ads get bigger in the smaller one. Such printing cylinders with differential pistons are known.

The invention has the purpose of making a special valve device Way of controlling the piston movement in the pressure cylinder. For this purpose are in one. Valve housing arranged two coaxial pistons under spring action. One end closes an annular space accessible to the hydraulic fluid away. It is also connected to one of the discharge lines of the pressure cylinder Provided longitudinal channel and is with the other end on the inner, as a valve seat formed end of the other piston on, who in turn of - Surrounded by a pressure chamber; and can be controlled from the outside. By pulling it out of the piston. the valve housing becomes the valve closure between the abutting ones The ends of the cage are opened and the hydraulic fluid is removed from the larger pressure cylinder space in; the return line to the pump is released with the result that the differential piston of the pressure cylinder is unlocked and from. Fluid pressure in the larger cylinder space can be moved.

A special embodiment of the controllable valve piston: has to The result is that the pressurized surfaces that cause the valve to close in the are essentially in the same relationship to one another as the unequal, large ones Piston surfaces of the two pressure cylinder spaces. This will. the control valve in his Starting position kept in equilibrium.

Further features of the invention emerge from the following Description and from the drawing, an exemplary embodiment is described in and illustrated eats.

The hydraulic system consists of a liquid container io, which is connected by line i i to the inlet of a continuously operating pump 12 is, through which the pressure fluid is conveyed into a memory 9, which in turn is connected to pressure line 13. The working cylinder-15 shown under 14 has a double-acting piston 16, which is on a piston rod 17 of relatively large diameter. The annular space 18 in which the piston rod 17 is located, is connected to the pressure line 13, while the working space i9 by line 2o is connected to the connection 2i of a valve 22. Line 13 stands with the connections 23 and 24 of the valve 22 in connection. A branch of line i i leads to return 25.

The valve 22 consists of a housing 26 with a bore 27. A sleeve 28 is seated in this, into which an adjusting screw 29 protrudes. A tubular valve body 30 is arranged axially displaceably in the sleeve 28. At the left end of the valve body 3o there is a frustoconical head 31 which seals against the annular seat 32 which is arranged on the sleeve 28. Behind the head 31 of the tubular valve body 30 is an annular groove 33; which through bore 34 with the pressure line 23 is in communication. At the right end of the valve body 3o there is an annular seal 35 in order to prevent liquid from escaping from the sleeve 28. The valve body 30 is held in its closed position by a spiral spring 36 in the space 37. When the valve is opened, the displacement of the valve body 3o is limited by the stop 38 which is screwed into the valve housing 26. Space 37 is connected to connecting line 21 through a bore 39.

A valve tappet 4o protrudes through a sealing sleeve 41 into the valve housing 26 into it. The inner end 42 is slidable in bore 27 and with an annular seal 43 provided. In this part of the plunger 4o there is a bore 44, which Mouthpiece in the shape of a truncated cone and used as a seat 45 for the rim 46 of the tubular valve body 3o is used. The diameter de: intermediate piece 47 des Valve tappet 40 is approximately: less than the part resting on the valve body 3o of the plunger 40, whereby a shoulder 48 is formed for receiving the sealing washer 49. Between this sealing washer and the sealing sleeve 41 is a Coil spring 5o, which is arranged so that when the valve is in its normal position (as shown in the drawing), one pressure after exercises left; substantially that exerted by the opposing spring 36 Pressure corresponds. The leakage of the liquid from the sealing sleeve 41 is through Ring seal 51 prevents.

The outer end of the valve tappet 40 is bifurcated to receive lever 52 which is connected to the valve tappet by bolts 53.

Bore 25 is connected by bore 54 to the annular space 55 which surrounds the seat surface 45, while the connecting piece 24 is connected to space 57 through bore 56 in a similar manner. Space 57 is completely closed off by bore 25 and surrounds shoulder 48 and spring 5o. Bore 44 is normally connected to port 2i via longitudinal bore 58 which extends from one end of valve body 30 to the other end.

The valve works as follows: The parts shown are in their normal release position. wherein the pressure fluid, which is conveyed by the pump 12, passes through connection 23 into the annular space 33. The pressure fluid from the pump 12 also acts on the annular working space 18 of the pressure cylinder; there it exerts a pressure on the piston 16 to the right in the drawing. However, a movement of the piston 16 to the right can only take place when the liquid can escape from the working chamber 19. When the valve is in the position shown, the liquid cannot escape, so that the working piston 16 is held in this position. One can easily see here that the only path through which the liquid could escape from the working space i9 runs through the bore 58 to the bore 44 and from here via the seat 45 to the container io. However, the liquid cannot take this course because the seat surface 45 is closed by the edge 46 of the valve body 30 . This closing of the seat surface is achieved by the pressure exerted by the spring 5o and is further increased by the fluid pressure acting in the space 57. The pressure fluid acts on an area which corresponds to the surface of the annular shoulder 48.

The pressure prevailing in the working space 18 of the working cylinder 14 and originating from the pump 12 generates a pressure in the working space 19 which is passed on through the line 20 and the bore 58 to the bore 44. This pressure therefore acts on valve tappets 40, specifically on an area which corresponds to that which is enclosed by the edge of the seat surface 46. The pressure fluid is supplied to the space 57 in order to withstand this pressure. The parts are constructed in such a way that the area of the shoulder 48 is in a certain ratio to the area delimited by the edge 46, namely in substantially the same ratio as between the effective areas of the working spaces 18 and ig of the working cylinder. If the area of the annular shoulder 48 is equal to A, the area of the valve seat 46 is equal to B, the effective area of the working space. 18 is set equal to C and the effective area of the working space ig is set equal to D, then AIB = CID.

The valve22 is thus in its initial position in equilibrium.

To move the piston of the working cylinder to the right, is the lever 52 moves to the right, whereby the seat surface 45 is lifted from the edge 46 and so the liquid from the larger working space ig of the working cylinder 14 can emerge. This liquid then flows through bore 54, connection 25 and line i i back to container io, while piston 16 through the pressure fluid is moved, which can flow into the working space 18.

Claims (4)

PATENT CLAIMS: i: Device for the pressure-dependent control of a hydraulic system in which the interior of a pressure cylinder is replaced by a differential piston is divided into two unequal sized rooms, of which the smaller one with the smaller one The piston area is under hydraulic pressure and the larger one with the larger piston area has a drainage facility for the hydraulic fluid, characterized in that that in a valve housing (22) two are under the action of springs (36.5o) coaxial pistons (30, 47) are arranged, one of which (30) with a End (31) closes off an annular space (33) accessible to the pressure fluid, a with the discharge line (2o) of the pressure cylinder (14) connected longitudinal channel (58) has- and with the other end (46) at the inner end designed as a valve seat (45) of the other piston (47), which in turn is enclosed by a pressure chamber (57) and can be controlled from the outside in such a way that by pulling out the piston (47) from the valve housing (26) and the opening of the valve closure caused thereby (45, 46) between the two pistons (30, 47) the hydraulic fluid from the larger one Space (ig) of the pressure cylinder (14) can flow into a return line (i i). 2. Device according to claim i, characterized in that the externally controllable valve piston (47) with a with the longitudinal channel (58) of the inner piston (3ö) communicating cavity (44) and inside the pressure chamber (57) at his Outside diameter is provided with a shoulder surface (48), the size (A) of the surface (B) of the valve closure (45, 46) between the pistons (30, 47) covering the cavity (44) is essentially in the same ratio as it exists between the surfaces (C, D) of the pressure cylinder spaces (18, ig). 3. Device according to claim i and 2, characterized in that the springs (36, 5o) of the two valve pistons (30, 47) are designed in such a way that they correspond to the pistons (30, 47) balance this acting fluid pressure. 4. Set up after Claim i to 3, characterized in that the movement of the inner valve piston (3o) is limited inwardly by a stop (38).