Hydraulic valve arrangement with control/regulating function

Abstract

The present invention relates to a hydraulic valve arrangement for controlling/regulating at least one hydraulic consumer of a mobile machine, with a summation interconnection of at least two hydraulic valves and at least one consumer interconnection of hydraulic valves, wherein the outputs of the summation interconnection are hydraulically connected with the inputs of the consumer interconnection, wherein at least one backflow valve is provided in the consumer interconnection. According to the invention, the at least one backflow valve for throttling a consumer return volume flow opens or closes in dependence on a consumer inflow pressure and comprises at least one main piston arranged in a bushing and at least two further pistons arranged in a lid separate from the bushing.

Claims

1. A hydraulic valve arrangement for controlling/regulating at least one hydraulic consumer (V1) of a mobile machine, with a summation interconnection of at least two hydraulic valves and at least one consumer interconnection of hydraulic valves, wherein the outputs of the summation interconnection are hydraulically connected with the inputs of the consumer interconnection, at least one backflow valve (R1, R2) is provided in the consumer interconnection, and for throttling a consumer return volume flow, the at least one backflow valve (R1, R2) opens or closes in dependence on a consumer inflow pressure and comprises at least one main piston (5b) arranged in a bushing (6b) as well as at least two further pistons (9b, 12b) arranged in a lid (2b) separate from the bushing (6b).

2. The hydraulic valve arrangement according to claim 1, wherein the at least one backflow valve (R1, R2) includes a pressure limitation function for limiting the consumer pressure to a maximum pressure level.

3. The hydraulic valve arrangement according to claim 1, wherein the hydraulic valve arrangement throttles the consumer return volume flow in dependence on external control signals.

4. The hydraulic valve arrangement according to claim 1, wherein at least one summation valve/inflow valve (S1, S2, Z1, Z2) is arranged in the summation interconnection and/or the consumer interconnection, the at least one summation valve/inflow valve (S1, S2, Z1, Z2) comprises at least two pistons (4a, 10a), and a main piston (4a) and a recoil piston (10a) are arranged in components designed separate from each other.

5. The hydraulic valve arrangement according to claim 1, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

6. The hydraulic valve arrangement according to claim 1, wherein the consumer interconnection is designed for controlling/regulating the directions of movement of at least one hydraulic consumer (V1), and/or in the consumer interconnection at least one summation valve/inflow valve (S1, S2, Z1, Z2) and at least one backflow valve (R1, R2) is provided for each direction of movement of the at least one hydraulic consumer (V1).

7. The hydraulic valve arrangement according to claim 1, wherein in the consumer interconnection two summation valves/inflow valves (S1, S2, Z1, Z2) and two backflow valves (R1, R2) are provided.

8. A backflow valve (R1, R2) for a hydraulic valve arrangement according to claim 1.

9. A hydraulic drive system with at least one hydraulic valve arrangement according to claim 1, with at least one hydraulic consumer (V1), wherein the at least one hydraulic consumer (V1) is hydraulically connected with the consumer interconnection, and/or with at least two hydraulic pumps (P1, P2), and the hydraulic pumps (P1, P2) are hydraulically connected with the summation interconnection.

10. A mobile machine with a hydraulic drive system according to claim 9.

11. The hydraulic valve arrangement according to claim 2, wherein the hydraulic valve arrangement throttles the consumer return volume flow in dependence on external control signals.

12. The hydraulic valve arrangement according to claim 11, wherein at least one summation valve/inflow valve (S1 S2, Z1, Z2) is arranged in the summation interconnection and/or the consumer interconnection, the at least one summation valve/inflow valve (S1, S2, Z1, Z2) comprises at least two pistons (4a, 10a), and a main piston (4a) and a recoil piston (10a) are arranged in components designed separate from each other.

13. The hydraulic valve arrangement according to claim 3, wherein at least one summation valve/inflow valve (S1, S2, Z1, Z2) is arranged in the summation interconnection and/or the consumer interconnection, the at least one summation valve/inflow valve (S1, S2, Z1, Z2) comprises at least two pistons (4a, 10a), and a main piston (4a) and a recoil piston (10a) are arranged in components designed separate from each other.

14. The hydraulic valve arrangement according to claim 2, wherein at least one summation valve/inflow valve (S1, S2, Z1, Z2) is arranged in the summation interconnection and/or the consumer interconnection, the at least one summation valve/inflow valve (S1, S2, Z1, Z2) comprises at least two pistons (4a, 10a), and a main piston (4a) and a recoil piston (10a) are arranged in components designed separate from each other.

15. The hydraulic valve arrangement according to claim 14, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

16. The hydraulic valve arrangement according to claim 13, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

17. The hydraulic valve arrangement according to claim 12, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

18. The hydraulic valve arrangement according to claim 11, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

19. The hydraulic valve arrangement according to claim 4, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

20. The hydraulic valve arrangement according to claim 3, wherein the summation interconnection adds up or separates volume flows supplied to the same on outputs provided at the same.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further details and advantages of the invention will now be explained in detail with reference to exemplary embodiments illustrated in the Figures, in which:

(2) FIG. 1: shows a schematic structure of a hydraulic drive system;

(3) FIG. 2: shows a hydraulic circuit diagram of the summation valve/inflow valve;

(4) FIG. 3: shows a cross-section of the summation valve/inflow valve;

(5) FIG. 4: shows a hydraulic circuit diagram of the backflow valve;

(6) FIG. 5: shows a cross-section of the backflow valve;

(7) FIG. 6: shows an opening cross-section in the seat sleeve with valve seat pressed in (version A);

(8) FIG. 7: shows an opening cross-section in the seat sleeve with integrated valve seat (version B);

(9) FIG. 8: shows an opening cross-section in the seat sleeve with form milling (version C); and

(10) FIG. 9: shows an opening cross-section, generated by form turning at the piston (version D).

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(11) The hydraulic control system can be configured as shown in FIG. 1. The hydraulic control system shown consists of at least two hydraulic pumps, a summation interconnection of at least two hydraulic valves, at least one consumer interconnection of hydraulic valves, and at least one hydraulic consumer (linear drive, rotational drive).

(12) The hydraulic pumps are hydraulically connected with the summation interconnection. By the summation interconnection, the volume flows of the hydraulic pumps can be added up or separated on correspondingly existing outputs of the summation interconnection. The summation interconnection can be arranged in a summation block or be realized by individual valve block arrangements. When realized by individual valve blocks, the valve blocks are connected with each other by hydraulic lines (tubes or hoses).

(13) The outputs of the summation interconnection are hydraulically connected with the inputs of the consumer interconnection. The outputs of the consumer interconnection are connected with the respective hydraulic consumers. The consumer interconnection serves for adjusting the direction of movement of a hydraulic consumer by selectively connecting the consumer ports either with the tank backflow or the inflow volume flows of the hydraulic pumps. The consumer interconnection can be arranged in a distributor block, so that for each consumer present in the hydraulic control system at least one distributor block performs the necessary functions. The consumer interconnection can, however, also be implemented by individual valve block arrangements, so that the hydraulic connections between the individual valve blocks are realized by hydraulic lines (tubes or hoses). It is also possible that several parallel distributor interconnections are provided for a hydraulic consumer.

(14) A similar system structure has been described already in the application DE 10 2012 004 012.1.

(15) Within the described hydraulic control system, the novel hydraulic valves should be usable in the form of different types of valve. They should be used either as summation valves within the summation interconnection, as inflow valves within the distributor interconnection and/or as backflow valves within the distributor interconnection.

(16) The inflow valves and backflow valves of a distributor interconnection should be used within the hydraulic control system for controlling the directions of movement of hydraulic consumers (linear drives, rotational drives). These hydraulic valves should be arranged such that for each direction of movement at least one inflow valve and at least one backflow valve can adjust the direction of movement of the hydraulic consumer. Thus, for each direction of movement at least one inflow valve (FIG. 1—Z1 and Z2) should be able to establish the connection between an inflowing pump volume flow (primary side) and the respective consumer port (secondary side). At the same time, at least one backflow valve (FIG. 1—R1 and R2) for each direction of movement correspondingly should be able to establish the connection between the respective consumer port (secondary side) and the tank backflow.

(17) The summation valves serve the assignment of pump volume flows to the consumers. Several pump volume flows can be added up on a consumer and also be separated again.

(18) To largely simplify the switching operations during the change of one summation state into another, the summation valves should include the following functions: The activation and deactivation of the function of the summation valves should be effected by an integrated solenoid switching valve (see FIG. 1—F5 and F6), which is actuated via an externally supplied electrical signal. When no control signal is applied, the summation valve should be deactivated, i.e. the valve is closed and cannot open. When a control signal is applied, it should be possible for the valve to open in dependence on the applied primary pressure (valve input) (primary pressure opening).

(19) When the function of the summation valve is enabled by applying the electrical control signal, the same initially is closed. When a pressure is built up at the inlet of the valve (primary side), this leads to the valve opening (primary pressure opening function). When the pressure is decreased before the valve or a deactivation is effected, the valve closes.

(20) Furthermore, the summation valves should have a recoil function, so that they will close, when the secondary pressure (pressure behind the summation valve) is higher than the primary pressure (pressure before the summation valve). This function has priority over the primary pressure opening function and is necessary in connection with the control of the summation valves.

(21) Resulting from the application of the described hydraulic control system in a mobile machine, in particular in a hydraulic excavator, the control system for example should have the following functions, which should be integrated into the inflow valves:

(22) The activation and deactivation of the function of the inflow valves should be effected by an integrated solenoid switching valve (see FIG. 1—F2 and F3), which is actuated via an externally supplied electrical signal. When no control signal is applied, the inflow valve should be deactivated, i.e. the valve is closed and cannot open. When a control signal is applied, it should be possible for the valve to open in dependence on the applied primary pressure (valve input) (primary pressure opening).

(23) When the function of the inflow valve is enabled by applying the electrical control signal, the same initially is closed. When a pressure is built up at the inlet of the valve (primary side), this leads to the valve opening. When the pressure is decreased before the valve or a deactivation is effected, the valve closes.

(24) Furthermore, the inflow valves should have a recoil function, so that they will close, when the secondary pressure (pressure behind the inflow valve) is higher than the primary pressure (pressure before the inflow valve). This function has priority over the primary pressure opening function and is necessary in the inflow valves for implementing a load-holding function of the consumers. The recoil function blocks a backflow of the primary-side volume flow into the pumps. It thereby is prevented on the one hand that the consumer sinks down due to a leakage by the pumps, and on the other hand the pumps are protected from pressure peaks proceeding from the consumer.

(25) In its application in a mobile machine, the hydraulic control system should be able to operate free from faults for various types of consumer (in a hydraulic excavator with backhoe equipment: hoisting cylinder, arm cylinder, bucket cylinder and traveling gear drives, etc.) in the four performance quadrants. Accordingly, hydraulic consumers must be able to pick up positive and negative loads in both directions of movement (in hydraulic linear drives: retraction/extension; in hydraulic rotational drives: counterclockwise/clockwise).

(26) In the case of negative loads, a device must be provided in the hydraulically open circuit of a hydraulic control system, which creates the possibility of braking the hydraulic consumer and adapt the same to its specified velocity, which is characterized by an imparted volume flow of the connected hydraulic pumps (outflow control). It should thereby be avoided that the hydraulic consumer is spontaneously accelerated by external loads. This would lead to a negative pressure on the primary side of the consumer, which can cause cavitation in the hydraulic control system. Due to the occurrence of cavitation, the hydraulic system components can be damaged, which should be avoided in any case.

(27) This connection should be realized as a function of the backflow valve within the consumer interconnection. The backflow valve should open or close in dependence on the consumer inflow pressure, in order to throttle the consumer return volume flow such that a corresponding consumer inflow pressure is maintained. Thus, the backflow valve should be adjusted directly by the hydraulic consumer inflow pressure.

(28) In its application in a mobile machine for various types of consumer (in a hydraulic excavator with backhoe equipment: hoisting cylinder drive, arm cylinder drive, bucket cylinder drive, traveling gear drives, etc.) the hydraulic control system should be provided with a secondary pressure limitation function. This function limits the consumer pressure (secondary pressure) to a maximum pressure level, in order to protect the hydraulic control system from overload of the individual hydraulic components. In the structure of a hydraulic control system as shown in FIG. 1, this function should be integrated into the backflow valves R1 and R2 such that in the case of too high a consumer pressure these valves provide for an opening from the consumer pressure side to the tank and hence limit the consumer pressure to a specified pressure level.

(29) The invention comprises the construction principles of the hydraulic valves, which provide for realizing the required and above-described functions for use in a hydraulic control system according to FIG. 1, in order to be used in a mobile machine.

(30) FIG. 2 shows the hydraulic circuit diagram and FIG. 3 a cross-section of the summation valve/inflow valve. These two valves (summation and inflow valves) are identical in their constructive design and their mode of operation.

(31) The entire valve construction is designed according to the principle of a built-in valve and is inserted into the valve block 1a into the standardized bore according to DIN ISO 7368 and fixed with a lid 2a. The axial positioning ensures the connection of the valve ports inflow A, outflow B and tank port T. The structure shown here is traversed exclusively from port A to B. When pressure is applied at port A, this pressure likewise is passed on through a connecting bore via recoil pistons 10a into the spring chamber 3a. Thus, the same pressures are applied on the two surfaces of the main piston 4a. Since the upper diameter of the main piston 4a is designed greater than the lower diameter, a force always acts on the main piston, which presses the same down onto the seat 6a. By the main spring 5a, which is biased, a further force is generated onto the main piston 4a, which acts downwards. In the unopened condition, the main piston 4a thus is pressed into the valve seat 6a by these two forces. The annular groove 7a always is connected to the tank.

(32) With unactuated release valve 8a, only shown in FIG. 2, the surface 9a of the recoil piston 10a is pressurized with tank pressure. Through a connecting bore, the pressure of port B is applied on the second surface 11a of the recoil piston 10a. Together with the spring 12a, the same acts against the pressure on the opposite surface 9a of the recoil piston 10a. Due to this pressurization of the recoil piston 10a, a comparison of the pressures at ports A and B is possible. When the recoil piston 10a is unactuated, a bore releases a connection of the spring chamber 3a and the high pressure, the valve remains closed. On actuation/release of the summation valve/inflow valve, a pressure is passed through the release valve 8a from port A onto the surface 9a of the recoil piston 10a, and a connection is created between the spring chamber 3a and the tank. The pressure in the spring chamber 3a is decreased, which leads to a stroke of the main piston 4a and clears a connection between ports A and B. When the release valve 8a is deactivated, a connection between high pressure and the spring chamber 3a again is created by the recoil piston 10a. As a result, the main piston 4a again moves into the valve seat 3a and thus closes the control edge. The flow between ports A and B is blocked.

(33) When the main control edge is opened and the pressure on port B rises above the pressure on port A, the ratio of forces pushes the recoil piston 10a into the same position as if the release valve 8a were deactivated. Via the connection with the recoil piston 10a, the spring chamber 6a thereby is pressurized with high pressure, whereby the main control edge is closed. When the pressure on port A again rises above the pressure on port B, the recoil piston 10a again is pressed into the stop via the surface 9a, the connection to the tank is established, and the main control edge opens again.

(34) FIG. 4 shows the hydraulic circuit diagram and FIG. 5 a cross-section of the backflow valve.

(35) The entire valve construction is designed according to the principle of a built-in valve and is inserted into the valve block 1b into the standardized bore according to DIN ISO 7368 and fixed with a lid 2b. The axial positioning ensures the connection of the valve ports inflow A, outflow B, the connection to the inflow pressure (p_inflow) and the tank port T. The structure shown here is traversed exclusively from port A to B. When pressure is applied at port A, this pressure likewise is passed on through the connecting nozzle 3b into the spring chamber 4b. Thus, on the upper and the lower side of the main piston 5b, which can move axially in the bushing 6b, the same pressures are applied. Since the upper diameter of the main piston 5b is designed greater than the lower diameter, a force always acts on the main piston 5b, which presses the same downwards. By the main spring 18b, which is biased, a further force is generated onto the main piston 5b, which acts downwards. In the unopened condition, the main piston 5b thus is pressed into the valve seat 7b by these two forces. The annular groove 8b always is connected to the tank. In the release valve of the backflow valve (not shown in FIG. 5), the port of the valve in the deactivated condition is connected with the tank line T. When the backflow valve is activated, the connection to T is blocked and the port is connected with the pressure chamber (inflow pressure) opposite the backflow. The inflow pressure thereby gets onto the control surface of the control piston 9b. This leads to a movement of the control piston 9b against two biased springs 10b from a defined value. Depending on the height of the inflow pressure, an opening surface exists between the spring chamber 4b and the control piston 9b, the volume of the spring chamber 4b is passed to the tank, selectively via a shuttle valve 11b, in order to influence the opening or closing speeds. The pressure drop in the spring chamber effects a stroke of the main piston 5b. Depending on the position of the main piston 5b, an opening surface is cleared, which provides for traversing the valve from A to B.

(36) When the inflow pressure (p_inflow) again drops below the defined value, the flow cross-section to the tank is blocked by the control piston 9b and connected with the high pressure. The pressure of port A therefore is applied in the spring chamber 4b, from where the same likewise is applied at the pressure limiting piston 12b. Via the adjusting mechanisms 14b, 15b, 16b, the same is biased with a spring 13b against the cone seat 17b. When the pressure on port A rises above an adjustable value, the pressure limiting cone 12b rises from the cone seat 17b and releases volume flow to the tank. The pressure in the spring chamber 4b thereby drops, which results in a force difference. Due to the force difference, the main piston 5b moves upwards and an opening surface between ports A and B is cleared. Based on this opening surface and the pressure difference between ports A and B, a volume flow is flowing, which leads to the fact that the pressure in port A is decreased.

(37) As shown in FIG. 6, the opening cross-section of the valve is determined by the axial position of the piston c1 in combination with the design of the seat sleeve c2. Due to different designs of the piston c1 and the seat sleeve c2, four combinations A, B, C and D are described below, which can equally be used for generating the opening surface of the inflow valve and of the backflow valve.

(38) In FIG. 6 the design of version A is shown. On the inside of the valve sleeve c2 a form turning is incorporated, which depending on the axial position of the piston c1 determines the flow cross-section. The sealing seat of the valve is realized by a sleeve c3, which is pressed into the valve sleeve c2 from below and on which the edge of the end face of the piston c1 rests, when the valve is closed.

(39) The version B for generating the opening surface is shown in FIG. 7. On the inside of the valve sleeve c2 a form turning is incorporated, which depending on the axial position of the piston c1 determines the flow cross-section. The sealing seat of the valve is directly incorporated into the seat sleeve c2 by a corresponding formation on which the end face of the piston c1 rests, when the valve is closed.

(40) The version C for generating the opening surface is shown in FIG. 8. In the valve sleeve c2 a form milling is incorporated, which depending on the axial position of the piston c1 determines the flow cross-section. The sealing seat of the valve is directly incorporated into the seat sleeve c2 by a corresponding formation on which the end face of the piston c1 rests, when the valve is closed.

(41) The version D for generating the opening surface is shown in FIG. 9. Here, a form turning is mounted on the piston c1, which depending on its axial position, in combination with the seat sleeve c2, determines the opening cross-section of the valve. The sealing seat of the valve is realized by a corresponding formation on the piston c1 and in the seat sleeve c2.