DE3313039A1 - CONTROL DEVICE - Google Patents

Description

R. 181 * 65

11.3.1983 Sf / Pi

ROBERT BOSCH GMBH, 7OOO STUTTGART 1

Control device
State of the art

The invention is based on a control device according to the preamble of the main claim. Such a one "Known control device has the disadvantage that" when Use of single-acting consumers on a directional valve with two consumer connections, one working connection must be closed. It must be in the relief position of the consumer, the draining pressure medium is routed via a pressure relief valve, with energy losses due to heating of the pressure medium and thus an overstressing of the hydraulic Plant.

Advantages of the invention

The control device according to the invention with the characteristic Features of the main claim has the advantage that it depends on the coupling state the position of the switching valve is controlled. It can one and the same directional valve can be used to control double-acting and single-acting consumers. If

only one single-acting consumer is connected, there are no more energy losses. Overloading of the hydraulic system is avoided Unneeded connection of the directional control valve is relieved with simple handling. The covering device the fluid coupling also serves as a protection against dirt and to control the switching valve.

Through the measures listed in the subclaims Advantageous developments and improvements of the features specified in the main claim are possible.

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the description below. 1 and 1a show a first embodiment of a control device, FIG. 2 shows an embodiment of a detail, FIGS. 3, 3 and 5 show a second, third and fourth embodiment, and FIG. 6 shows an embodiment of a second detail.

Description of the exemplary embodiments

In FIG. 1, 10 denotes a pump which sucks in pressure medium from a tank 11 and displaces it via a line 12 and a branch line 13 to a 6/3 way valve lh. This has the connections a, b, c on one side and the connections d, e, f on the other side. The line 12 opens at connection a, the branch line 13 opens at b, and a line 15 leads from c to the tank 11. A line 1d, 17 with a fluid coupling 18, 19 is arranged at each of the connections e and f. The fluid coupling 19 is via a

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Line 20 with the rodless space 2J 'des Cylinder 21 connected. Parallel to the line 16 is A switching valve 23 with flow position I and blocking position II is connected via a line 22, the via a line 2U with a check valve arranged therein 25 is connected to a line 26. The latter leads from connection d of the directional control valve 1U to a second 6/3-way valve 27 and on to a container. The switching valve 23 is controlled by a spring 29 in the Flow position I held and mechanically via a Device 31, which is operatively connected to the fluid coupling 19 is in the locked position .11.

An exemplary embodiment for actuating the primary switching valve 23 is shown in FIG. In front of the opening 32 of a cup-shaped nut piece 33 with an external sliding sleeve 3 ^ is a cover plate trained locking device 35 is arranged. This is connected by means of a rigid connection 36 to the switching valve 23 so that this in flow position when not coupled I is located. A male piece 37 designed as a plug can be inserted into the opening 32 of the female piece for coupling 33 are inserted and is held by the sliding sleeve 3U. Then there is a connection from the Line 16 to line 2l ·.

The aim is to use one and the same directional valve to control a single or double-acting Cylinder. In the case of a single-acting cylinder, only the space 21 'of the cylinder 21 without a piston rod is present Connected via the fluid coupling 19 to the directional valve 1U and thus to the pump 10 or the container JI.

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the. The fluid coupling 18 is not coupled. That from The pressure medium conveyed by the pump 10 flows through the directional control valve which is in switch position I "lowering" " 1U into line 16 and from there via the held by the spring 29 in the flow position I. Switching valve 23 into line 2 ^. Got from here the pressure medium now through the check valve 25, the Line 26 and the directional valve 27 to the container 28 without energy loss.

If the closure device 35 is pushed away from the nut piece 33, the switchover valve is activated at the same time 23 moved into the locking position II by means of the rigid connection 36. The reflux of the pressure medium to container 28 is blocked. The father piece 37 can now be plugged into the nut piece 33, so that a connection to the piston rod side 21 ″ of the cylinder 21 is established. The cylinder 21 can now also operated as a double-acting cylinder.

Without deviating from the basic idea of the invention, the shifting of the switchover valve 23 is according to FIG also possible electrically or hydraulically. It is crucial that the position of the switching valve 23 and thus the pressure medium flow as a function of the coupling state is controlled, and the connection that is not required is always relieved via the switching valve 23. For example The movement of the slide sleeve 3 ^ can also be used to move the switching valve 23 will.

As shown in FIG. 1 a, the switching valve 23 a line 39 lead directly to the container 28. The directional control valve 27 is only necessary if there are more

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Consumers are connected to the pump 10. If the directional control valve is 1 h in neutral position II, then all of the pressure medium delivered by the pump 10 flows through the directional control valve 27 to the container 28. If the directional control valve lh is switched from its neutral position II to the position III "lift", the reverses Liquid flow with respect to the cylinder 21 µm.

In the embodiment of Figure 3, a 7/3-way valve h ^ with the switching positions I, II and III and the connections ^ a, b, c on one side and d to g on the other side is used to control the pressure medium. From connection e a line 1 + 2 leads directly to the switching valve 23 and at flow position I from there via a line 1 + 3 to the container 28. This line 1 + 3 is connected to the connection d of the directional control valve U1 via the line i + 5 . The switching valve 23 is also connected to the fluid coupling 18 via the device 31.

The switching valve 23 is in the flow position I, in switching position II of the directional control valve 1 + 1 flows the pressure medium conveyed by the pump 10 both via the line 1 + 5 and via the switching valve 23 the container 28. For a single-acting cylinder is here in switching position I "lowering" an unpressurized circulation of the pressure medium conveyed by the pump 10 is possible. Will If the cylinder 21 is used as a double-acting cylinder, the piston chamber 21 ″ is connected via the fluid coupling 18 connected to the pressure medium circuit. The switching valve 23 is, as shown in Figure 2, during the coupling process moved into the locking position II. It can "lower" or "raise" in switch positions I and III a pressure build-up takes place in each case, the discharge to the container 28 is blocked.

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The embodiment of Figure h differs from that of Figure 3 only in that the switching valve 23 is built into the directional control valve hl . The switching valve 23 is connected via a branch channel kQ in the directional control valve h 1 to the channel U9, which leads from the connection a to the connection d. The channel 50 connects the switching valve 23 to the connection e. The switching valve 23 can be actuated, for example, by turning the control slide, if it is a known rotary or longitudinal slide device. The installation represents a compact and simplified handling for the user, but does not change the actual mode of operation.

The exemplary embodiment according to FIG. 5 represents a modification of that according to FIG. 3. In addition a changeover valve 52 is also connected in parallel to the pump 10 here. From a line 53 which the Pump 10 connects to connection b, leads a branch line 5 ^ to an end face 52 "of the switching valve 52 and a branch line 55 with a throttle point 56 to the other end face 52 '. The branch line 55 is still connected by means of the line 57 with .dem connection a of the directional control valve H1. To this A spring 58 acts on the end face 52 ′ of the switchover valve 53.

The switching valve 52 has a flow position T and a blocking position II on; a line 59 leads from the line 53 to the switching valve 52 and from there further back to tank 11 via line 60.

If the pump 10 delivers full and no consumer is connected, a pressure is generated at the throttle 56

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gradient. The switching valve 52 is switched to flow position I because the pressure force in the line 5 * + the force of the spring 58 predominates. The pressure medium thus flows back to the container 11 via the line 53, the switchover valve 52 and the line 6θ. Pressure medium flowing through the throttle 56 flows into the container kh . If, on the other hand, a consumer is connected, no large pressure gradient can arise at the throttle 56. The switching valve 52 is switched to the blocking position II by the force of the spring 58. All of the pressure medium supplied by the pump 10 flows to the consumer.

In Figure 6, an embodiment of the switch valve 23 is shown together with the actuating device. The housing 63 of the combined switching valve 23 plus coupling 18 has a central, continuous longitudinal bore 65 with an inlet opening 66 with a smaller cross-section and on the other side an opening 6 ¹ J for the father piece 77 of the coupling 18 on. An outlet opening 68 is arranged downwards at right angles to the inlet opening 66. A cup-shaped control slide 69 is slidably guided in the longitudinal bore 65. This is pressed by the force of a spring TO against a shoulder 71 in the longitudinal bore 65. In the bottom 72 of the control slide 69, two obliquely running through bores 73, 7 ^ · are formed and a plunger 75 is arranged in the middle of the opening 67. A cylindrical male piece 77 is slidably guided in the opening 67. A plurality of locking balls 79j, which are movably arranged in a recess 80 in the housing 63, engage in the approximately center, outer circumferential annular groove 78 on the male piece 77. On the outer wall of the housing 63 is a sliding sleeve 81 with an inner

yj <J

-X

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lying annular groove 82 out. When the clutch is opened, the locking balls 79 dip into the annular groove 82 of the sliding sleeve 81, while at up to the shoulder
71, the male piece 77 pushed into the annular groove 78
are pressed in the father piece 77. A central channel 83 is formed in the male piece 77 and is connected to the piston rod side 21 ″ of the cylinder 21 via a line 8U.

In the uncoupled state, the control slide 69 is pressed by the spring 70 against the shoulder 71.
As a result, the opening 67 is shut off tightly, and the pressure medium flows through the outlet opening 68 to the container. If the male piece 77 is now coupled, the control slide 69 is displaced by means of the plunger 75 against the force of the spring 70, so that the outlet opening 68 is now completely blocked. That
Pressure medium can flow through the bores 73, 7 ^, via the channel 83 and the line Qh to the cylinder 21. The cylinder 21 now works as a double-acting cylinder.

Claims (1)

R. 18465 11.3.1983 Sf / Pi ROBERT BOSCH GMBH, 7OOO STUTTGART 1 Expectations {1.} Control device for a hydraulic system with a Directional valve, to whose consumer connections fluid couplings are connected, via which pressure medium to single- or double-acting consumers, characterized in that one of the consumer connections a switching valve (23) is connected, which by one of the coupling state of a fluid coupling (18) actuated precaution (31) from one of the relevant consumer connection with a return connection (24) opposing the connecting flow position a spring force (29) is switched into a blocking position. ■ - 2. Control device according to claim 1, characterized in that in series with the multi-way valve (1U, 41) a second multi-way valve (27) is connected, and that the return connection (24) via a check valve (25) is also connected to this connection (26). 3. Control device according to claim 1 and / or 2, characterized characterized in that the multi-way valve (U1) has a second Has neutral circulation (42). 134 "U. Control device according to one of claims 1 to 3, characterized in that the switching valve (23) is arranged in the multi- way valve {h'l) . 5. Control device according to one of claims 1 to k, characterized in that the fluid coupling (18) is designed as a plug-in coupling. 6. Control device according to one of claims 1 to 5, characterized in that the switching valve (23)
is connected to a closure device (35) of the fluid coupling (18) and is controlled by moving the closure device (35). T. Control device according to one of claims 1 to 6, characterized in that the switching valve (23)
is connected in parallel to one of the consumer connections (18). 8. Control device according to one of claims 1 to 7, characterized in that the switching valve (23)
an in particular approximately cup-shaped slide (69)
with a passage (73) in the bottom (72) and is formed in the nut piece (6U) of the fluid coupling (18). 9. Control device according to claim 8, characterized in that the bottom (72) of the slide (69) is a
The plunger (75) is arranged from the male piece (77)
the clutch can be actuated. 10. Control device according to claim 1 to 9, characterized
characterized in that the switching valve (23) is ^{controlled by moving the sliding sleeve (3 1} +, 81).