DE2521367C2 - Hydraulic system - Google Patents

Description

The invention relates to a hydraulic system for supplying a consumer according to the preamble of the main claim.

From DE-OS 22 18 391 a radial piston pump with a control pin on which a rotor can rotate is stored, gotvt. There are star-shaped cylinders in the rotor formed, which alternately with suction and pressure grooves in the control pin in the rotation of the rotor Overlap come. Pistons are slidably guided in the cylinders, with their outwardly directed Front sides rest against the inner contour of a ring surrounding the rotor. The stroke ring is eccentric arranged to the rotor with the eccentricity by two diametrically opposite, on the circumferential contour of the stroke ring acting control piston is changeable. These two control pistons are different large diameter, the control piston with the smaller diameter om the pump outlet pressure is acted upon and presses the cam ring into a position that has a lower eccentricity compared to the Has rotor. The control piston with the large diameter is held in contact with the stroke ring by a spring and also by the pump outlet pressure applied. Due to the larger effective area of the control piston with its large diameter, the latter When pressure is applied to both piston pistons, the control piston is pressed into a position that has a large Has eccentricity relative to the rotor. the

so pressurization of the control piston with the large diameter is controlled by a valve, whereby when a certain level of the pump outlet pressure is reached, the control piston with a large Diameter is shut off from the pump outlet pressure and connected to the low pressure side of the pump. As the pump outlet pressure continues to act on the small diameter control piston, This control piston pressed the cam ring into a position that has a lower eccentricity compared to the Has rotor, so that the delivery rate of the pump is reduced again. Since when starting this Pump the eccentric ring pressed into a position of maximum eccentricity by the spring-loaded piston is. the consumer will immediately get a high

h5 amount of pressure medium, d. H. a pressure surge !. Such pressure surge c. which among consumers, such as / .. U. Pressure accumulator can lead to damage, ireten with this pump, in particular, often

if the drive speed fluctuates significantly. This is the case, for example, when the pump is from the internal combustion engine a motor vehicle is driven.

In GB-PS 8 50425 a hydraulic system is described in which one driven at a constant speed adjustable vane pump an adjustable flow rate for the linear, alternating movement of the slide of a machine tool. The GB-PS is based on the task of a specific adjustable flow rate for driving a hydraulic consumer, even with variable loads of the hydraulic consumer to keep constant.

However, the hydraulic system has the following disadvantages:

When this pump starts up or when it starts up from a low speed, the eccentric ring is through a spring-loaded piston pressed into a position of maximum eccentricity or almost maximum eccentricity As a result, the consumer is immediately subjected to a pressure surge, since the control is independent from system pressure works.

The system also has a pressure relief device, which consists of a throttle valve and a Pressure relief valve exists. When a predetermined pressure is reached, this is released by the pressure relief valve held; the opening process when the predetermined pressure is exceeded creates a Pressure difference at the throttle valve, whereby the pump goes into neutral position. Since the predetermined pressure in the Consumer line is maintained, the pump works while maintaining a minimum flow rate not relieved of pressure. The pump can be manually relieved by the manual valve provided will; However, here too, the counteracting movement into the neutral position is needed to overcome As a result of the spring force of the spring, a residual pressure is required so that the pump is not completely depressurized.

In DE-Fo 8 49 3Ί5 is a pump control for a controllable radial piston pump for supplying a hydraulic power lift described, be> which the adjustable race of a pressure-dependent sliding one Adjusting piston when the pressure increases in the supply line from an idle position in the direction larger funding volume is postponed. The pressure increase takes place due to a throttle point for the Lcer circulation liquid circulation. which is formed by the displacement of a control device. These Pump control has the disadvantage, however, that the actuation of the preselection device of the control device and thus the production of a pressure medium delivery state is not based on the pressure medium requirement of the consumer is controlled. A quantity-dependent pump control is used in this control for a hydraulic one Power lift not provided either.

DE-AS 10 97 188 is a pressure control valve for Hydraulic systems are known in which the control body carrying the button and feeler surface is made of frictional connection parts held in connection or forms a single component. This pressure valve works with a check valve that opens towards the consumer, the supply line being pressure-dependent can be switched off by the consumer and connected to a return. This known device does not contain any the pump delivery flow continuously adjustable from an idle state to a maximum delivery state Device, but the pressure valve is switched on or off in two states.

The object of the invention is to create a hydraulic system of the type indicated, in which the switching the control pump between an idle state ■ 5 with minimal delivery and a pressure medium delivery state depending on the pressure medium requirement of the consumer through a simply structured, given Switching points exactly and reliably working switching valve can be controlled and in which the control pump is depressurized when idling.

According to the invention, this object is achieved by the characterizing features specified in the main claim solved.

Since the pump only delivers the required amount when pressure medium is required by the consumer, i. h "there only If there is very little delivery in the return, the energy consumption of the pump is reduced to a minimum

In a hydraulic system according to the invention that is used to supply a consumer? serves, is it favorable when the piston of the pressure compensator provides a control pressure for adjusting an adjusting piston of the device regulates

This pressure compensator advantageously has a control cylinder, which is axially displaceable by the Piston is divided into a high pressure chamber and a spring chamber that the high pressure chamber with the Supply line in front of the diaphragm and the spring chamber connected to the supply line behind the diaphragm is that a compression spring is arranged in the spring chamber, which is located at the bottom of the spring chamber and acts on the end face of the piston directed towards the spring chamber that in the cylindrical Wall of the control cylinder leading to the device and to the return that can be shut off by the switching valve Connecting line opens, which after displacement of the piston in the high pressure chamber up to End position is connected to the spring chamber, and after moving the piston in the spring chamber up is connected to a return to the end position. Furthermore, there is a favorable design of this pressure compensator in that the piston with a first and a second circumferential radially on its cylindrical lateral surface Control groove is formed that from the first control groove radial bores in an axial bore of the Lead piston that opens into the spring chamber that the first control groove after displacement of the piston in the high pressure chamber is in overlap with the connecting line up to the end position and that the second Control groove after moving the control piston into the spring chamber to the end position with the connecting line and is in overlap with the return.

With dicfer directly acting pressure compensator is It is advantageous that the piston of the pressure compensator is a stepped piston and that the piston on the large piston;! area of the Stepped piston acting pressure in the supply line behind the orifice pressurizes the large piston area.

An exemplary embodiment of the invention is shown in the drawing and is described in more detail below.
It shows

Fig. 1 shows a hydraulic system for supplying a Consumer,

F i g. 2 another hydraulic system for supply of a consumer.

The hydraulic systems in FIG. 1 and 2 have control pumps I, the pressure connection 2 via a

Supply line 3 is connected to terminal 4 of a consumer 45. In connection 4 of consumer 45, a switching valve 6 is arranged, which can be switched as a function of the pressure prevailing at connection 4. A return flow of pressure medium from the consumer 45 to the control pump 1 is prevented by a check valve 7 arranged in the supply line 3, which blocks a pressure medium flow counter to the flow direction 8 from the control pump 1 to the consumer 45. In the supply line 3, a diaphragm 11 is arranged between the check valve 7 or the connection 4 and the pressure connection 2 of the control pump 1. Connections 9 and 10 lead from the supply line 3 in front of and behind the diaphragm 11 in this way to a hydraulic pressure compensator 12 and 12 ', respectively. that the two active surfaces of this pressure compensator 12 and 12 'can be acted upon by the pressure in front of and behind the diaphragm. This pressure compensator 12 and 12 ', acts on a device i3 mi Vei change of ruitipenriuucs liei Regeipumpe 1 in the way. that with increasing pressure drop at the orifice 11, the pump stroke is adjusted in the sense of a delivery rate reduction. Conversely, this also means that the pump stroke is adjusted when the pressure drop at the diaphragm 11 is reduced in the sense of an increase in the delivery rate.

In Fig. 2, the pressure compensator 12 consists of a control cylinder 14, in which a piston 15 is guided axially displaceably. This piston 15 becomes the control cylinder 14 into a high pressure chamber 16 and into a spring chamber 17 divided, the high pressure chamber 16 with the supply line 3 in front of the diaphragm 11 and the spring chamber 17 is connected to the supply line 3 behind the diaphragm 11. One in the spring chamber 17 arranged compression spring 18 is supported on the bottom 19 of the spring chamber 17 and acts on the spring chamber 17 directed end face 20 of the piston 15 a different one. dsß the piston! 5 in the high pressure piston! 6 is moved. The piston 15 is on its cylindrical outer surface with two radially circumferential control grooves 21. 22 provided, with radial bores 23 from the first control groove 21 in a central Axialbohrur.g 24 lead which opens into the spring chamber 17. Another control groove 25 in the cylindrical lateral surface of the control cylinder 14 and a likewise opening into the cylindrical outer surface of the control cylinder 14 Return 26 are arranged so that after displacement of the piston 15 in the high pressure chamber 16 to towards the end position, the control groove 25 in the control cylinder 14 partially overlaps the first control groove 21 in the piston 15 is. and that after the piston 15 has been moved into the spring chamber 17 up to the end position, the control groove 25 in the control cylinder 14 with the second control groove 22 in the piston 15 and this with the mouth of the return 26 is partially covered.

One leads from the control groove 25 in the control cylinder 14 Connecting line 27 to an adjusting cylinder 28 of the device 13 for changing the pump stroke. In addition, this connecting line 27 leads through a chamber 29 of a pressure valve 64, which is in the open position is connected to a return 30.

The connecting line 27 is connected in parallel to the supply line 3, in the direction of flow 8 the check valve 7 is arranged behind the diaphragm 11 is. that opens to consumer 45. The pressure valve 64 and the check valve together form the Switching valve 6.

An adjusting piston 31 can be displaced in the adjusting cylinder 28 of the device 13 for changing the pump stroke guided and is with one end face 32 on the pivotable eccentric ring 33 of the control pump 1 at. The connecting line 27 opens into one between the actuating piston 31 and the bottom 34 of the actuating cylinder cylinder chamber 35 formed. One on the eccentric ring 33 the .Stellkolben 31 lying opposite The restoring piston 36 loaded by a spring 67 presses over the eccentric ring when the cylinder chamber 35 is relieved of pressure 33 the actuating piston 31 up to the plant of the

ίο actuating piston 31 on the bottom 34 of the actuating cylinder 28 in the cylinder chamber 35. This position means the smallest eccentricity of the eccentric ring 33 to the cylinder block 37 of the regulating pump 1, so that it only promotes a small flow of pressure medium.

The pressure valve 64 has an axially displaceable switching piston 38, which with einir. End 39 protrudes into a pressure chamber 40 connected to consumer 45. The other end 41 of the switching column 38 rests against the intermediate piece 42, if the filter direction of the valve is pressurized by a compression spring 43. The intermediate piece 42 and the compression spring 43 are arranged in a spring chamber 44, from which the return line 30 leads to a container 46. A pin 47 of the intermediate piece 42 largely protrudes through a connecting bore 48 which leads from the spring chamber 44 to the chamber 29. A closure piece 49, which is formed by a ball, is attached in the chamber 29 and is pressed by a compression spring 50 with minimal biasing force onto the valve seat opening 51 of the connecting bore 48 to the chamber 29. The force of the compression spring 43 corresponds approximately to the product from the effective piston area of the end 39 of the switching piston 38 protruding into the pressure chamber 40 and a certain maximum switching pressure which corresponds to the maximum accumulator pressure in the consumer 45. The negative spring characteristic of the compression spring 43 allows accurate and rapid opening of the Shah ^<r entils 6 when reaching the maximum allowable storage pressure.

When the hydraulic system is started up, the regulating pump 1 first delivers a minimal pressure medium flow. so that there is only a slight pressure gradient at the diaphragm 11. Since the effective areas of the piston 15 according to FIG. 2 of the pressure compensator 12 are the same size and since the piston 15 by the compression spring 18 in the End position in the high pressure chamber 16 is pressed, the supply line 3 is behind the diaphragm 11 on the Spring chamber 14, the axial bore 24, the radial bores 23, the control grooves 21 and 25 and about the Connecting line 27 connected to the cylinder chamber 35 of the device 13 for changing the pump stroke.

The one in the supply line 3 behind the panel 11 The pressure prevailing is therefore also present in the cylinder chamber 35 and moves the actuating piston 31 afterwards right, so that the eccentric ring against the spring-loaded The return piston is pivoted about the bolt 52 in the sense of an increase in the pump stroke. Through this the delivery rate increases, as a result of which the pressure gradient at the diaphragm 11 also increases. Will the differential pressure at the diaphragm 11 is greater than the force of the compression spring 18 of the pressure compensator 12. so the piston 15 shifted to the left, so that the control groove 25 comes into overlap with the control groove 22. Since now the Cylinder chamber 35 via the connection line 27 and the control grooves 25 and 22 with the return 26 is in connection. the pressure builds up in the cylinder chamber 35 from. so that the eccentric ring 33 by the spring loaded

siclcn return piston 36 in the sense of a pump stroke reduction is reset and the delivery rate of the pump drops again. It takes place;>. Lso when driving the Regcl pump 1 with intermittent speed anyway an approximately equal flow rate of the pump.

If the consumer 45 is filled so far that the maximum accumulator ^{pressure is reached in it, move 1} -! Jeser accumulator pressure acting on the switching piston 38, the switching piston against the force of the compression spring 43, so that the locking piece 49 by the pin 47 of the mouth 51 the verb ^; Round bore 48 is lifted and the chamber 29 is connected to the return 30 via the connecting bore 48 and the spring chamber 44. The pressure prevailing in the cylinder chamber 35 is thereby reduced and the eccentric ring 33 of the control pump 1 is reset in the sense of a reduction in the pump stroke, so that only a minimal delivery of pressure medium takes place.

D-ΐ with a ΠΊ! Π! ΓΠ?. | ΡΠ FörHprstrnm also only pin ppringes There is a pressure gradient at the diaphragm 11 the piston 15 is in its end position in the high pressure skiimmer, so that the low pressure medium flow conveyed Via the connection 9 and the connecting line 27 to the chamber 29 and further through the connecting bore 48 and the spring chamber 44 reaches the return 30. Only when the accumulator pressure drops below the maximum permissible value, the pressure valve 64 closes again, so that the consumer 45 through the Control pump 1 is again supplied with a uniform constant flow of pressure medium.

In F g. 1, the pressure compensator 12 'consists of a cylinder 53, in which a stepped piston 54 is displaceably guided. This stepped piston 54 divides the cylinder

53 into a large cylinder chamber 55 and a small cylinder chamber 56. A step 57 of the stepped piston 54 penetrates the bottom of the small cylinder chamber 56 through a bore 58 and rests with its end face the pivotable eccentric ring 33 of the radial piston pump 1. When the cylinder chambers are depressurized 55, 56 is the eccentric ring 33 by a ίο Spring 67 loaded restoring piston 36 pressed against step 57 of stepped piston 54 until the stepped piston

54 rests against the bottom 60 of the large cylinder chamber 55 with a stop 59. In this position the Eccentric ring 33 has the lowest eccentricity compared to the cylinder block 37.

A line 9 connects the supply line 3 in front of the diaphragm 11 with the small cylinder chamber 56. A connecting line 10 leads from the supply line 3 to a chamber 29 of the pressure valve 64 and from this chamber 29 on to the large cylinder chamber 55 of the cylinder 53.

When commissioning the hydraulic system according to FIG. 1, the regulating pump 1 first delivers a minimum Flow rate. As a result of this minimal delivery flow, there is also only a minimal flow at the diaphragm 11 Pressure gradient, so that the stepped piston 54 to the right is shifted, since the pressures in the large cylinder chamber 55 and the small cylinder chamber 56 approximately are the same, but the stepped piston 54 has the larger effective piston area towards the large cylinder chamber By shifting the stepped piston 54 to the right, the eccentric ring 33 is around the Bolt 52 is pivoted against the spring-loaded reverse piston 36 so that its eccentricity is opposite the cylinder block 37 enlarged. As the pump stroke increases, so does the delivery rate increased, so that the pressure gradient across the diaphragm 11 increases. This also increases the pressure in the small cylinder chamber 56 faster than the pressure in the large cylinder chamber 55. The pressure gradient at the aperture 11 so large that the product from the Small piston area 63 and the pressure in the small cylinder chamber 56 is greater than the product of the large piston area 62 and the pressure in the large cylinder chamber 55, the stepped piston moves

54 again to the left, whereby the eccentric ring 33 is also again in a position of lesser eccentricity the cylinder block 37 and thus pivots to a smaller pump stroke. This also sinks again Delivery rate of control pump 1.

Achieved in the system according to FIG. 1 the pressure in the pressure accumulator 45 is its maximum permissible value, so opens the switching valve 6, as in FIG. 2 already described, the connection from the chamber 29 via the connecting bore 48 and the spring chamber 44 to return 30 Dor pressure in rlpr prnfipn 7vlinHprkammpr

55 degrades, so that the control pump 1 adjusts to minimum delivery. This minimum flow rate is diverted via the connecting line 10 to the chamber 29 and from there to the return 30. Only when they fall away the storage pressure below its maximum permissible value, the switching valve 6 closes the connection again to the return 30, so that the control pump 1 the consumer 45 again with a constant pressure medium flow can supply.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Hydraulic system for supplying a consumer, in particular a pressure accumulator, with a control pump, the delivery rate of which depends on the amount by changing the effective pump stroke can be regulated, with one arranged in the supply line from the regulating pump to the consumer Switching valve and with one in the supply line between the control pump and the Switching valve arranged orifice and a hydraulic pressure compensator, the two effective areas of which from Pressure in front of or behind the diaphragm can be pressurized, so that the piston of the hydraulic Pressure compensator in the sense of a flow rate reduction with increasing pressure drop at the orifice and conversely to a device for Vei change which is prestressed in one direction by resilient means of the? umpenhubes of the regulating pump acts, with a switched on in the supply line 'Pressure valve with two switching positions is provided, via which the supply line to the device is connectable, characterized in that that the resilient means (67) on the device (13) in the sense of a delivery rate reduction act, and a non-return valve (7) opening towards the consumer (45) in the supply line (3) is switched on, the pressure valve (64) switching depending on the consumer (45), with a Schal'Volben (38), which in the closing direction of the Pressure valve (64) is actuated by its own compression spring (43) with a negative characteristic curve, and the Pressure valve (64) the control pump (1) when the Non-return valve (7) connects to the return line (30). 2. Hydraulic system according to claim 1, characterized in that the piston (15) of the Pressure compensator (12) regulates a control pressure for adjusting an actuating piston (31) of the device (13). 3. Hydraulic system according to one of the preceding claims, characterized in that the Pressure compensator (12) has a control cylinder (14), which by the axially displaceable piston (15) in a high pressure chamber (16) and a spring chamber (17) is divided, that the high pressure chamber (16) with the supply line (3) in front of the diaphragm (11) and the spring chamber (17) with the supply line (3) is connected behind the diaphragm (11) that the spring chamber (17) a compression spring (18) is arranged is, which is supported on the bottom (19) of the spring chamber (17) and directed towards the spring chamber (17) End face (20) of the piston (15) acts that in the cylindrical wall of the control cylinder (14) one to the device (13) and the connecting line leading to the return line (30) which can be shut off by the switching valve (6) (27) opens, which after displacement of the piston (15) in the high pressure chamber (16) to is connected to the end position with the spring chamber (17) and which after displacement of the piston (15) into the Spring chamber (17) is connected to a return (26) up to the end position. 4. Hydraulic system according to claim 3, characterized in that the piston (15) with a first and a second control groove (21 and 22) running radially around its cylindrical lateral surface 'is trained. that of the first control groove (21) radial bores (23) in an axial bore (24) of the Lead piston (15) which opens into the spring chamber (17) that the first control groove (21) after displacement of the piston in the high pressure chamber (16) up to the end position with the connecting line (27) is in overlap, and that the second control groove (22) after displacement of the piston (15) in the spring chamber (17) to the end position with the connecting line (27) and with the return (26) in Coverage is 5. Hydraulic system according to one or more of the preceding claims, characterized that the piston of the pressure compensator (12 ') is a stepped piston (54) and that the on the large Piston surface (62) of the stepped piston (54) acting pressure in the supply line (3) behind the orifice (11) the large piston area (62) is pressurized.