DE4004854A1 - Hydraulic controller with changeover valve for two pumps - has two positions of slider selected in accordance with pressure for throttling of low-pressure flow - Google Patents

Abstract

A high-pressure pump (12) and a low-pressure pump (11) are driven jointly by a motor (14) and their output lines (15,17) pass through a changeover valve (19) with a slider (25) spring-biased (26) to an initial position in which high- and low-pressure inputs (21,23) are cross-coupled (28). Without blocking of the high-pressure line (15), the flow in the low-pressure line (17) can be throttled to the higher level. USE/ADVANTAGE - Esp. in high-pressure gear-changing and low-pressure lubrication system. Constant-rate tandem gear-wheel pump (13) can be used requiring relatively low power.

Description

State of the art

The invention is based on a hydraulic control device according to the preamble of claim 1.

It is already such a hydraulic control device for the utility a high-pressure circuit and a low-pressure circuit known with pressure medium from two individual pumps, the pressure medium via a changeover valve optionally to the two circuits is distributed. Such hydraulic control devices are mostly unsuitable for special uses, especially if in one Tractor engine a transmission control and a lubricating oil circuit supplied with pressure medium in the simplest and optimal way should be, especially if the size of the volume flows and their Pressures in both circles are very different.

Advantages of the invention

The hydraulic control device according to the invention with the kenn The drawing features of the main claim have the opposite part that they are inexpensive with the simplest possible design  and compact control unit that enables a high pressure circuit and a low pressure circuit with very different volumes current requirements supplied with pressure medium. The also works Control device with a relatively low power requirement, wherein as a hydraulic drive unit, a constant tandem gear pump can be used.

The measures listed in the subclaims provide for partial training and improvements in the main claim specified control device possible. It is possible to hire a hydraulic, pressure-dependent changeover of the changeover valve tils on increased volume flow in the direction of the high pressure circuit too to provide an electrical switchover. Furthermore, the order Switch valve advantageously designed so that it is the volume flow to the high pressure circuit keeps constant. An extremely useful Lö Solution arises according to claim 7 if the integration of Measuring throttle in the changeover valve a particularly compact and pure hydraulic switching can be achieved, which is especially true for mobile Use cases is advantageous. Further advantageous embodiments conditions result from the drawing and the description.

drawing

Five embodiments of the invention are shown in the drawing represents and explained in more detail in the following description. It demonstrate

Fig. 1 shows a first embodiment of the hydraulic control device according to the invention in a simplified representation, FIGS. 2 to 5 each part of a second to fifth embodiment of the invention and Fig. 6 as a detail, the switching valve of FIG. 5 in an enlarged scale and in a simplified Presentation.

Description of the embodiments

Fig. 1 shows a hydraulic control device 10 , which has a first pump 11 with a relatively large delivery volume and a second pump 12 with a relatively small delivery volume for pressure medium supply, both of which are designed as a gear pump 13 and driven by a motor 14 be. The delivery volume of the first pump 11 is approximately six times the delivery volume of the second pump 12 , both of which are constant pumps.

The second pump 12 for high pressure conveys pressure medium 15 to a hydraulic transmission control 16 , which represents the so-called high-pressure circuit, via a high-pressure line. The first pump 11 supplies a low-pressure line 17 to a lubricating oil circuit 18 with pressure medium, which here det the low-pressure circuit bil. Both circuits for high pressure and low pressure are arranged on a tractor engine, not shown.

Both lines 15 and 17 lead via a changeover valve 19 , which has a high-pressure inlet 21 and a high-pressure outlet 22 for this purpose, while the low-pressure line 17 corresponds in this way to a low-pressure inlet 23 and a low-pressure outlet 24 is led. The changeover valve 19 has a control slide 25 which is pressed into the drawn starting position 27 by a spring 26 . In this starting position 27 , the two high-pressure connections 21 , 22 are connected to one another, as are the two low-pressure connections 23 and 24 . Furthermore, in this starting position 27 there is a cross connection 28 between the high pressure inlet 21 and the low pressure inlet 23 , while the low pressure outlet 24 is immediately connected to a first throttle point 29 . The spool 25 is from this starting position 27 out against the force of the spring 26 in a first working position 31 and a second working position 32 deflectable. In the first working position 31 , the high pressure line 15 or the low pressure line 17 is in each case fully opened. In the second Ar beitsstellung 32 , the first throttle point 29 is missing, while in the cross-connection 28 a second throttle point 33 is connected and the high-pressure output 22 is immediately connected upstream of a third throttle point 34 .

A measuring orifice 35 is located in the high-pressure line 15 between the changeover valve 19 and the transmission control 16 . The pressure in the high pressure line 15 in the area between the switching valve 19 and Meßblen de 35 is tapped and acts via a control line 36 on an end face 37 of the spool 25 , so that it moves depending on the pressure against the force of the spring 26 in its working positions 31 , 32 bar is.

The high-pressure pump 12 is secured via a pressure relief valve 38 , which is connected upstream of the changeover valve 19 to the high-pressure line 15 , which additionally has a check valve 39 opening to the high-pressure line 15 opening to the outlet of the low-pressure pump 11 . Furthermore, the Niederdrucklei device 17 is secured downstream of the switching valve 19 via a pressure valve 41 to a tank 42 . If the changeover valve 19 fails , the low pressure line 17 is also pressurized with high pressure and is protected by the pressure relief valve 38 .

The mode of operation of the control device 10 is explained as follows, reference being made to the special requirements of the two circuits with regard to pressure and quantity. The term high-pressure circuit does not mean an absolutely high pressure, but a much higher pressure level than the low-pressure circuit.

First, the functional state should be considered that the gear in the transmission control 16 is shifted, the two circuits 16 and 18 receiving pressure medium flows with their specific pressure-Men genwert. The gear pump 11 promotes its pressure medium flow as a rule to the low-pressure circuit 18 , this lubricating oil circuit being set to a pressure of approximately 3 bar by means of the pressure valve 41 . The volume flow to the lubricating oil circuit 18 is relatively large, and it can be five to eight times the flow rate for the high-pressure pump 12 . The volume flow of the second pump 12 flows through the changeover valve 19 into the high pressure circuit 16 , the pressure level at the pressure relief valve 38 being able to be secured, for example, to a height of 20 bar. It should be assumed that an operating pressure of approximately 18 bar must be provided for the transmission control 16 , this pressure being referred to as high pressure in the present context. This operating pressure acts on the control line 36 on the control slide 25 of the changeover valve 19 and adjusts it against the force of the spring 26 in its second working position 32nd The pressure-dependent switching valve 19 is so out with its throttling points that it maintains this operating pressure of 18 bar for the transmission control 16 . In addition, the volume flow to the transmission control 16 is also determined with the help of the orifice 35 in the second working position 32 to a certain flow rate, which can be, for example, 10 to 15 liters per minute. This Druckmit telstrom is necessary to ensure the operating pressure in the transmission control 16 despite the existing leaks in controls, shafts, Druckölzufüh, piston seals, etc.

In the following, the functional state when changing gear should be considered. When shifting into another gear, the transmission control 16 requires an increased volume flow for a short time, since a new pressure piston in the transmission must be actuated there. In addition, however, the operating pressure of 18 bar must still be maintained. For the cylinder filling when changing gears, a larger amount of oil is required for a short time, the peak of which can be a multiple of the delivery rate of the second pump 12 , for example can reach an order of magnitude of approximately 40 liters per minute.

When changing gears, the operating pressure drops by approx. 2 bar during the changeover. This per se permissible pressure drop, which occurs only briefly, is effective via the control line 36 on the control slide 25 , whereby the latter is moved by the spring 26 over the first working position 31 into the starting position 27 . The volume flow to the lubricating oil circuit 18 is throttled to the operating pressure of approximately 18 bar via the first throttle point 29 and a considerable part of the flow rate of the first pump 11 flows via the cross-connection 28 in addition to the transmission control 16 , so that the transmission control 16 with a volume flow is supplied, the size of which can be two to three times the delivery volume of the second pump 12 . At the same time, the other part of the flow of the first pump 11 flows into the low-pressure circuit 18 , where the pressure valve 41 continues to provide a pressure of a few bar. This throttling and reversing part of the För der quantity of the first pump 11 takes only a short time, and can be a period of about 0.5 to 1 second. If the process of changing gears is ended, that is, the cylinder is filled, the control spool 25 is again adjusted to its operating position 32 with increasing operating pressure, whereupon the gear shifted functional state occurs again. The check valve 39 ensures that the first pump 11 is also secured via the pressure relief valve 38 when the volume flow in the low-pressure line 17 is throttled.

The control device 10 thus allows for a relatively simple, compact and therefore inexpensive design that a high pressure circuit 16 and a low pressure circuit 18 are supplied with pressure medium in an optimum manner in accordance with their respective pressure and quantity requirements. He can achieve increased volume flow in the direction of high-pressure circuit 16 by simple hydraulic switching of the switching valve 19 . The control device 10 also builds particularly inexpensively because the changeover valve 19 is designed as a simple switching valve, which is why the increased volume flow to the transmission control 16 is still dependent on the volume flow of the pump.

FIG. 2 shows part of a second control device 50 which differs from the first control device 10 according to FIG. 1 as follows, the same reference numerals being used for the same components.

In the second control device 50 , the changeover valve 19 is designed as a control valve 51 , in which a first ( 52 ) or second intermediate position 53 serving as a transition zone is formed between the starting position 27 and the two working positions 31 , 32 . In the first or second intermediate position 52 , 53 , the second throttle point 33 is already effective in the cross-connection 28 , while the first throttle point 29 in the low-pressure side 17 and the third throttle point 34 in the high-pressure side 15 have no effect.

The mode of operation of the second control device 50 differs from that of the first control device 10 only in that the volume flow flowing to the transmission control 11 is constantly regulated by the control valve 51 , regardless of the sizes of the volume flows of the pumps 11 and 12 .

FIG. 3 shows part of a third control device 60 , which differs from the second control device 50 according to FIG. 2 as follows, the same reference numerals being used for the same components.

The control slide 25 of the control valve 51 is additionally acted upon on its end face loaded by the spring 26 via a control channel 61 with the pressure in the high-pressure line 15 downstream of the measuring valve 35 . Furthermore, a Dros sel 62 is connected in the control line 36 . From the end face pressurized via the control line 36 on the control slide 25 , a control connection 63 leads to the tank, into which a switching 2/2 solenoid valve 64 is switched.

The mode of operation of the third control device 60 differs from that of the second control device 15 as follows: the control valve 51 operates as a pressure scale assigned to the measuring orifice 35 , which keeps the volume flow in the direction of the transmission control 16 constant, regardless of the pump speed. During a changeover process in the transmission control 16 to a new gear, the 2/2 solenoid valve 64 is actuated independently of the drop in pressure. When the solenoid valve 64 is energized, it switches from a blocking position into an open position, one end face of the control slide 25 being relieved via the control connection 63 , and the spring 26 switching the control slide 25 into its initial position 27 . This limits the volume flow to the low-pressure circuit 18 and controls an increased volume flow to the transmission control 16 . When the gear shift is complete, the solenoid valve 64 that is switched off is also returned to its locked position by spring force and the control valve 51 can again function as a pressure compensator and the pressure circuit 18 again with its normal volume flow. With the third control device 60 , a switching device of the control valve 51 to increased volume flow in the direction of the high-pressure circuit 16 can thus be carried out electrically, namely with the aid of the magnetic valve 64 .

Fig. 4 shows a part of a fourth control device 70 , which differs from the third control device 60 of FIG. 3 mainly by the fact that the first measuring orifice 35 with the help of an electromagnetically actuated switching valve 71, an auxiliary Meßblen de 72 is connected in parallel . With this additional auxiliary Meßblen de 72 can be achieved in an advantageous manner that the increased volume flow even after switching the control valve 51 via the two auxiliary measuring orifices 35 , 72 connected in parallel is kept th th. When changing gear, a uniform Ge speed profile of a shift piston can be achieved over the path, i.e. regardless of the shifting force. If the gear shift in the transmission control 16 is ended, the switching valve 71 is switched off again. Since the electrical switching function is perceived by Schaltven valve 71 , the switching valve 64 according to FIG. 3 with the associated control connection 63 and throttle 62 can be omitted.

Fig. 5 shows part of a fifth control means 80, which differs from the fourth control means 70 according to Fig. 4 especially since by that the functions of the metering orifice 35 and the auxiliary metering orifice 72 directly gelventil in the operating as pressure compensator Re 81 are integrated, the control valve 81 being switchable purely hydraulically. Otherwise, the same components as in Fig. 5 are given the same reference numerals.

In the control valve 81 , as shown enlarged in FIG. 6, the measuring orifice 35 is located directly in the control slide 25 and is there directly connected upstream of the high-pressure outlet 22 . The pressure in the high pressure line directly before the orifice plate 35 is tapped in the control slide 25 and a control output 82 supplied to the the tapped pressure on the Fe of 26 against opposite end face of the control slide valve 25 via the control line 36th The size of the orifice plate 35 is the same size in the two working positions 31 and 32 and the intermediate position 53 and corresponds to the orifice plate 35 in the fourth Steuereinrich device 70 according to FIG. 4. The size of the orifice plate 35 in the initial position 27 and in the first intermediate position 52 , on the other hand, is larger than in the other switching positions 31 , 32 , 53 and corresponds to the sum of the orifice plate 35 and auxiliary orifice plate 72 according to FIG. 4. When switching over in the transmission control 16 , the re regulating valve 81 switches automatically and purely hydraulically, as in the control device 10 according to FIG. 1, in the starting position 27 . There is no magnetic reversal required as in the fourth control device 70 according to FIG. 4. In the initial position 27 , an increased volume flow flows into the high-pressure circuit 16 , this increased volume flow also being kept constant by the larger measuring orifice 35 in the initial position 27 . The fifth control device 80 thus enables the same functions as the fourth Steuerein device 70 according to FIG. 4, but electrically operated valves are omitted and a purely hydraulic reversing is possible.

Of course, changes to the embodiments shown are possible without departing from the spirit of the invention. In particular, the orifice plate 35 can be made adjustable if necessary.

Claims (12)

1. Hydraulic control device for supplying a high-pressure circuit, in particular for a transmission control, and a low-pressure circuit, in particular for a lubricating oil circuit, with pressure medium from two pumps with the help of a changeover valve, characterized in that the changeover valve ( 19 ) has a high pressure input ( 21 ) and a high-pressure outlet ( 22 ), via which a high-pressure line ( 15 ) leads to the high-pressure circuit ( 16 ) that a low-pressure line ( 17 ) via a low-pressure input ( 23 ) and a low-pressure outlet ( 24 ) is guided to the low-pressure circuit ( 18 ) that in the high-pressure line ( 15 ) a measuring orifice ( 35 ) is connected and by a spring ( 26 ) in the direction of an initial position ( 27 ) loaded control slide ( 25 ) of the changeover valve ( 19 ) from the pressure in the high-pressure line ( 15 ) upstream of the measuring orifice ( 35 ) against the force of the spring ( 26 ) and that de r spool ( 25 ) of the Umschaltven valve ( 19 ) from the starting position ( 27 ) depending on pressure in at least two working positions ( 31 , 32 ) is displaceable. 2. Control device according to claim 1, characterized in that the switching valve ( 19 ) in the starting position ( 27 ) connects the high-pressure connections ( 21 , 22 ) and the low-pressure connections ( 23 , 24 ) to each other, a cross-connection ( 28 ) between the high-pressure inlet ( 21 ) and the low-pressure inlet ( 23 ) and the low-pressure outlet ( 24 ) is connected to a first throttle point ( 29 ) before that the control slide ( 25 ) in a first working position ( 31 ) in each case only the high-pressure line ( 15 ) and the low-pressure line ( 17 ) open and that in the second working position ( 32 ) in the cross-connection ( 28 ) a second throttle point ( 33 ) is connected and the high-pressure output ( 22 ) A third throttle point ( 34 ) is connected upstream. 3. Control device according to claim 1 or 2, characterized in that the switching valve ( 19 ) for controlling a constant volume flow to the high pressure circuit ( 16 ) as a control valve ( 51 , 81 ) is formed, which between the starting position ( 29 ) and the two working positions ( 31 , 32 ) each have a first or second intermediate position ( 52 , 53 ) serving as a transition zone. 4. Control device according to one or more of claims 1 to 3, characterized in that the changeover valve ( 19 ) is designed as a Druckwaa ge ( 51 ), the end face of the control slide ( 25 ) loaded by the spring ( 26 ) via a control channel ( 61 ) is additionally acted upon by the pressure in the high-pressure line ( 15 ) downstream of the measuring orifice ( 35 ). 5. Control device according to one of claims 1 to 4, characterized in that the switching valve ( 19 ) via a in a to the tank ( 42 ) guided control connection ( 63 ) lying Schaltven valve ( 64 ) is pilot-controllable. 6. Control device according to one of claims 1 to 4, characterized in that the measuring orifice ( 35 ) an auxiliary measuring orifice ( 72 ) can be switched in parallel with the aid of a switching valve ( 71 ). 7. Control device according to one of claims 1 to 5, characterized in that the measuring orifice ( 35 ) in the control slide ( 25 ) of the order switching valve ( 81 ) is arranged and the switching valve ( 81 ) has a control connection ( 82 ), the pressure of which Control slide ( 25 ) against the force of the spring ( 26 ) acted upon. 8. Control device according to one or more of claims 1 to 7, characterized in that the pumps ( 11 , 12 ) are designed as tandem gear pumps ( 13 ), of which the low-pressure pump has a larger delivery rate than the high-pressure pump. 9. Control device according to one of claims 1 to 8, characterized in that the low-pressure circuit ( 18 ) downstream of the changeover valve ( 19 ) is secured by a first pressure valve ( 41 ). 10. Control device according to one of claims 1 to 9, characterized in that the high-pressure pump ( 12 ) is secured by a pressure limiting valve ( 38 ) and via a high-pressure valve ( 15 ) opening check valve ( 39 ) with the low-pressure pump ( 11 ) is connected. 11. Control device according to one of claims 1 to 10, characterized in that the tandem pumps ( 13 ) and the switching valve ( 19 ) are arranged in a common housing or block. 12. Control device according to claim 7, characterized in that the measuring orifice ( 35 ) in the starting position ( 27 ) and the first intermediate position ( 52 ) has a larger cross section than in the two working positions ( 31 , 32 ) and the second intermediate position ( 53 ).