WO2011006465A1 - Hydraulic system - Google Patents

Abstract

The invention relates to a hydraulic system comprising a pressure reducer designed as a sliding valve with positive engagement, comprising a tank connection, a system pressure connection and a working pressure connection that can be connected to the system pressure connection or the tank connected via the pressure reducer, a working pressure acting upon a valve slide of the pressure reducer via a control line, which working pressure is made available by means of the working pressure connection, and further comprising a return. The invention is characterized in that an additional volume flow is discharged from the working pressure connection via a hydraulic resistance and is fed to an additional consumer to maintain the valve slide on a control edge in critical situations.

Description

 Hvdrauliksvstem

The invention relates to a hydraulic system with a designed as a slide valve with positive overlap pressure reducing valve having a tank port, a Systemdruckan- connection and a working pressure port, which is connectable by the pressure reducing valve with the system pressure port or the tank port, wherein a valve spool of the pressure reducing valve via a control line with a working pressure is provided, which is provided via the working pressure port, and with a return.

From the international publication WO 2007/003151 A1, pressure reducing valves are known which connect the working pressure either with the tank pressure or with the system pressure or occupy intermediate positions in order to steplessly modulate the working pressure.

The object of the invention is to improve the response of a pressure reducing valve in a hydraulic system according to the preamble of claim 1 in critical situations.

The object is in a hydraulic system with a valve designed as a positive overlap valve pressure reducing valve having a tank port, a system pressure port and a working pressure port, which is connectable by the pressure reducing valve to the system pressure port or the tank port, wherein a valve spool of the pressure reducing valve via a control line with a Working pressure is applied, which is provided via the working pressure port, and with a return, solved in that an additional volume flow is discharged via a hydraulic resistance from the working pressure port and another consumer is supplied to hold the valve spool in critical situations at a control edge. The further consumer is preferably a cooling device and / or a lubricating device and / or a pilot circuit of a hydraulic valve or the tank. If the additional volume flow is led to other consumers, so that they have to take correspondingly less volume flow directly from the system, the permanent flow through the hydraulic resistance is not considered to be additional leakage, since it does not remain unused. The object is further in a hydraulic system with a designed as a positive overlap valve pressure reducing valve having a tank port, a system pressure port and a working pressure port, which is connectable by the pressure reducing valve to the system pressure port or the tank port, wherein a valve spool of the pressure reducing valve via a Control line is supplied with a working pressure, which is provided via the working pressure port, and with a return, achieved in that the return via an additional valve and a hydraulic resistance to the working pressure port is connectable to the valve spool in critical situations at or near a Hold control edge. The pressure reducing valve is preferably designed as a 3/2-way valve with positive coverage or as a 3/3-way valve. The tank connection communicates with a tank containing a working medium, such as hydraulic oil, which is subjected to a tank pressure, preferably ambient pressure. At least one consumer is connected to the working pressure connection. The consumer is, for example, a hydraulic cylinder, in particular an adjusting cylinder for a CVT transmission, a gear adjusting cylinder for an automated manual transmission or for a dual-clutch transmission or a clutch cylinder. In a positive overlap zone, the valve spool can move away without changing the working pressure. The positive overlap is needed to prevent working fluid from constantly flowing through the pressure reducing valve during operation. If the working fluid is relatively cold, the positive coverage, for example, due to viscous friction of the valve spool, may adversely affect the responsiveness of the pressure reducing valve. In such critical situations, ie in particular at low temperatures, the valve spool is held according to an essential aspect of the invention by a targeted volume flow at or in the vicinity of the control edge. This significantly improves the response in critical situations.

A preferred embodiment of the hydraulic system is characterized in that in critical situations via the additional valve, the hydraulic resistance and the pressure reducing valve, an additional volume flow, in particular via the tank connection or the tank, is discharged. The additional volume flow is preferably removed only at low temperatures. At high temperatures, the additional volume flow is switched off.

Another preferred embodiment of the hydraulic system is characterized in that the additional valve is designed as a check valve. About the kickback til and the hydraulic resistance always reaches working fluid to the working pressure connection when the working pressure is lower than the return pressure.

Another preferred embodiment of the hydraulic system is characterized in that the check valve comprises a valve spring. The valve spring is preferably biased so that the check valve opens only from a certain pressure difference.

A further preferred embodiment of the hydraulic system is characterized in that the additional valve is designed as a 2/2-way valve, which connects the Arbeitsdruckan- conclusion in critical situations with the tank. Instead of the tank can be used in the context of the present invention, a return tank or drain. The additional 2-way valve opens the additional volume flow.

Another preferred embodiment of the hydraulic system is characterized in that the 2/2-way valve is connected via a control line to the return. When a threshold value is exceeded, working fluid flows from the working pressure port via the hydraulic resistance and the 2/2-way valve into the tank. The control of the 2/2-way valve via the return pressure.

Another preferred embodiment of the hydraulic system is characterized in that the hydraulic resistance is designed as a diaphragm. Alternatively, the hydraulic resistance may be designed as a throttle. The hydraulic resistance is matched to the temperature behavior of the working fluid.

A further preferred embodiment of the hydraulic system is characterized in that the output of a pump is connected to the system pressure port, wherein the return from a branch between the output of the pump and the system pressure port emanates. Via the return, the output of the pump is connected to the inlet of the pump and / or to the tank.

Another preferred embodiment of the hydraulic system is characterized in that a pressure limiting valve is arranged in the return. The pressure relief valve ensures that the output of the pump is connected to the input of the pump or the tank only after a certain pressure value. - A -

A further preferred embodiment of the hydraulic system is characterized in that a cooler and / or a filter are arranged in the return line / is. The cooler serves to cool the working medium returned via the return. The filter is used to filter the discharged via the return working medium.

Another preferred embodiment of the hydraulic system is characterized in that a hydraulic cylinder is connected to the working pressure port. The hydraulic cylinder is preferably an adjusting cylinder, such as a gear adjusting cylinder of an automatic gearbox or a dual-clutch gearbox or a clutch cylinder, which is controlled by a transmission control by means of the pressure reducing valve.

Further advantages, features and details of the invention will become apparent from the following description in which, with reference to the drawings, various embodiments are described in detail. Show it:

1 shows a hydraulic circuit diagram of a hydraulic system according to a first embodiment with a check valve,

Figure 2 is a similar hydraulic system as in Figure 1 with a 2/2-way valve and

Figure 3 is a similar hydraulic system as in Fig. 1 without additional valve.

In Figures 1, 2 and 3, a hydraulic system 1; 41 is shown with a hydraulic cylinder 2 in the form of a hydraulic circuit diagram according to two different embodiments. The hydraulic cylinder 2 is, for example, an adjusting cylinder of a continuously variable conical-pulley belt drive, a gear adjusting cylinder in a transmission or a clutch cylinder. The hydraulic cylinder 2 is supplied via a pump 4 from a tank 5 with a working fluid. The working medium is a hydraulic medium, in particular hydraulic oil. The working medium is sucked in from the tank 5 via a suction line 6. Between the pump 4 and the hydraulic cylinder 2, a pressure-reducing valve 8 is connected for the control of the same, which is designed as a proportional valve and electromagnetically or hydraulically actuated. The pressure reducing valve 8 is designed as a 3/2-way valve with a positive coverage or as a 3/3-way valve. A system pressure connection of the pressure reducing valve 8 is connected via a connecting line 11 to an outlet of the pump 4 in connection. A tank connection of the pressure reducing valve 8 is in communication with the tank 5. A working pressure connection of the pressure reducing valve 8 is connected via a working pressure line 12 with the hydraulic cylinder 2 in connection. From the working pressure line 12 is a control line 14, through which a valve spool of the valve designed as a slide valve pressure reducing valve 8 is acted upon by the working pressure. The control line 14 of the pressure reducing valve 8 is also referred to as pressure feedback.

From the connecting line 11 is a return 15, which connects the connecting line 11 with an input of the pump 4 and with the tank 5. In the return 15, a pressure control valve 16 is arranged, which connects the connecting line 11 and the output of the pump 4 in response to the pressure at the outlet of the pump 4 and the pressure in the connecting line 11 with the input of the pump 4 and the tank. In the return 15, a cooler 17 and a filter 18 is further arranged.

The working pressure connection or the working pressure line 12 is connected to the system pressure connection or the connecting line 11 or the tank connection or the tank 5 via the pressure reducing valve 8 as required with any intermediate positions. Between the open position to the tank and the system pressure open position, a third position or coverage zone is arranged in which all three ports are closed by the valve spool. In this overlap zone or third position, the valve slide can travel away without the working pressure in the working pressure line 12 changing significantly. This third position or coverage zone, which is also referred to as a positive overlap, is required so that in operation, hydraulic medium does not flow back continuously from the working pressure line 12 via the working pressure connection and the pressure reducing valve 8 into the tank 5.

Clutch cylinder, gear adjusting cylinder or adjusting cylinder have the peculiarity that they are actually carried out tight and only record or release volume flow when they travel paths, for example, to drive over a clearance. If, however, a Wet clutch is applied, it reacts quite stiff and the clutch cylinder hardly moves even with pressure changes. The same applies to adjusting cylinder, if a bevel gear ratio is to be kept at changing moment, for example in Stützbedarf. This causes a pressure reducing valve 8 when used with a clutch cylinder, a gear adjusting cylinder or an adjusting cylinder as a hydraulic cylinder 2, when the pressure is to be kept constant, often work in the overlap. In the case of a subsequent change request, that is to say pressure build-up or pressure reduction in the hydraulic cylinder 2, the valve slide must then often be moved only within the overlap in order to reach the control edge of the pressure-reducing valve 8.

At normal operating temperature, reaching the control edge is not a problem. However, at low temperatures, that is, low hydraulic fluid temperature, the overlap due to the viscous friction of the valve spool and increased damping of the finite orifices in the transmission control may result in an undesirably long response time and even increase Stability problems due to the dead time to the response of the pressure reducing valve 8 lead.

Furthermore, a flat behavior of the pressure reducing valve 8 in the overlap with a sharp bend to steep characteristics and outside of the overlap easily lead to an unstable behavior of the pressure regulator, since the damping of the hydraulic system 1 must be tuned to either the steep characteristic part or the flat behavior. If the steep part is sufficiently damped, then this can lead to unsatisfactory dynamics in the coverage.

By the invention, the response of the pressure reducing valve 8, in particular in the cold, improved without the basic design of the pressure reducing valve 8 must be changed. According to one essential aspect of the invention, the valve spool of the pressure reducing valve 8 is held in the previously described critical situations, especially in the cold, by a targeted flow in the working pressure port or out of this on its control edge. With an inlet into the hydraulic cylinder 2, the valve slide is preferably held at a tank edge. During an outflow from the hydraulic cylinder 2, the valve spool is preferably held at a system pressure control edge. Although the additional volume flow is an additional leakage, but does not matter in the cold, since the control volume of the pressure reducing valve 8 is preferably tuned to high gap leakage in the heat. As input for the provision of the additional volume flow, the return pressure is used, which reaches about 4 bar in normal operation, for example. In the cold, the return pressure can reach 20 bar and more.

In the embodiment shown in Figure 1, the return line 15 via an additional line 20 to the working pressure line 12 is connectable. The additional line 20 is based on a branch 21 of the return line 15, which is arranged between the pressure regulating valve 16 and the radiator 17. The additional line 20 opens at a further branch 22, which is provided between the pressure reducing valve 8 and the hydraulic cylinder 2, in the working pressure line 12th

In the additional line 20, starting from the branch 21, an additional valve 25 and a hydraulic resistor 28 are connected in series. The additional valve 25 is designed as a check valve. The hydraulic resistor 28 is designed as a diaphragm. Through the additional valve 25 and the hydraulic resistor 28 hydraulic fluid from the return line 15 is always passed into the working pressure line 12 when the pressure at the branch 22, which is also referred to as working pressure, less than the pressure at the branch 21, which is also is referred to as radiator return pressure.

In the embodiment shown in Figure 2, the working pressure line 12 is connected via an additional line 60 to the tank. The additional line 60 starts from a branch 61, which is arranged in the working pressure line 12 between the pressure reducing valve 8 and the hydraulic cylinder 2. In the additional line 60, an additional valve 65 and a hydraulic resistance 68 are arranged. The hydraulic resistor 68 is designed as a diaphragm and connected in series between the branch 61 and the additional valve 65. The additional valve 65 is designed as a 2/2-way valve, which is biased by a spring in the illustrated closed position. The additional valve 65 is acted upon via a control line 70 with the return pressure. The control line 70 starts from a branch 72, which is arranged in the return line 15 between the pressure relief valve 16 and the radiator 17. When a threshold value defined by the prestressed spring is exceeded, the additional valve 65 is actuated via the control line 70, that is, switched to its opening division, not shown in FIG. 2, in which the working pressure line 12 communicates with the tank 5 via the additional line 60 and the orifice 68 stands. In the embodiment of Figure 2, it is optionally possible to use the discharged from the tank drain of the valve 65 hydraulic medium for other tasks in a transmission, such as CVT, automated manual or dual-clutch transmission. The use can consist for example in the lubrication and / or cooling of components. Another possibility of use can be done in the hydraulic control itself, for example, by the feed into the pilot circuit of a valve, in particular the pressure reducing valve. 8

The valve 65 for interrupting the flow of the hydraulic medium from the working pressure line 12 according to Figure 2 may even be omitted. This embodiment of the invention is shown in FIG. The additional volume flow discharged from the working pressure line 12 is therefore supplied directly to a consumer 66, which may be a device for lubricating and / or cooling and / or a pilot circuit and / or a fluid tank. The embodiment according to FIG. 3 is particularly preferred when the additional volume flow to other consumers 66 results in the fact that they have to remove correspondingly less oil flow directly from the system. The permanent flow would then not be regarded as additional leakage. The other consumer 66 may be the pilot circuit of the pressure reducing valve 8.

LIST OF REFERENCES

hydraulic system

 hydraulic cylinders

 pump

 tank

 suction

 Pressure reducing valve

 connecting line

 Working pressure line

 control line

 returns

 Pressure control valve

 cooler

 filter

 additional line

 branch

 branch

 additional valve

hydraulic resistance

 hydraulic system

 additional line

 branch

 additional valve

 consumer

hydraulic resistance

 control line

 branch

Claims

claims

A hydraulic system comprising a pressure reducing valve (8) designed as a positive overlap gate valve having a tank port, a system pressure port, and a working pressure port connectable to the system pressure port or the tank port by the pressure reducing valve (8), wherein a valve spool of the pressure reducing valve is connected via a pressure relief valve Control line (14) is acted upon by a working pressure which is provided via the working pressure port, and with a return (15), characterized in that an additional volume flow via a hydraulic resistor (68) discharged from the working pressure port and another consumer (66) is supplied to hold the valve spool in critical situations at a control edge.

2. Hydraulic system with a designed as a positive overlap valve pressure reducing valve (8) having a tank port, a system pressure port and a working pressure port which is connectable by the pressure reducing valve (8) with the system pressure port or the tank port, wherein a valve spool of the pressure reducing valve via a Control line (14) is acted upon by a working pressure, which is provided via the working pressure port, and with a return (15), characterized in that the return (15) via an additional valve (25; 65) and a hydraulic resistance (28; ) is connectable to the working pressure port to hold the valve spool in critical situations at a control edge.

3. Hydraulic system according to claim 2, characterized in that in critical situations via the additional valve (25; 65), the hydraulic resistance (28; 68) and the pressure reducing valve (8), an additional volume flow is dissipated.

4. Hydraulic system according to one of claims 2 or 3, characterized in that the additional valve (25) is designed as a check valve.

5. Hydraulic system according to claim 2 or 3, characterized in that the additional valve (65) is designed as a 2/2-way valve, which connects the working pressure port in the critical situations with the tank (5) or with other consumers.

6. Hydraulic system according to claim 5, characterized in that the 2/2-way valve via a control line (70) is connected to the return (15).

7. Hydraulic system according to one of the preceding claims, characterized in that the hydraulic resistance (28; 68) is designed as a diaphragm.

8. Hydraulic system according to one of the preceding claims, characterized in that the output of a pump (4) is connected to the system pressure port, wherein the return (15) emanating from a branch between the output of the pump (4) and the system pressure port.

9. Hydraulic system according to one of the preceding claims, characterized in that a pressure limiting valve (16) is arranged in the return line.

10. Hydraulic system according to one of the preceding claims, characterized in that a hydraulic cylinder (2) is connected to the working pressure port.