EP2633129A1

EP2633129A1 - Hydraulic arrangement

Info

Publication number: EP2633129A1
Application number: EP11776751.7A
Authority: EP
Inventors: Mario Seebode; Thilo Kazimiers
Original assignee: Deere and Co
Current assignee: Deere and Co
Priority date: 2010-10-29
Filing date: 2011-10-26
Publication date: 2013-09-04
Anticipated expiration: 2031-10-26
Also published as: US20130219874A1; DE102010043135A1; EP2633129B1; WO2012055917A1; US9284966B2

Abstract

The invention relates to a hydraulic arrangement (10) for increasing an engine load. The hydraulic arrangement comprises a hydraulic load (28), a load pressure-controlled hydraulic pump (24), a hydraulic tank (26), and a hydraulic control circuit (30) which is connected to the hydraulic load (28) and with which a volume flow rate that is conducted from the hydraulic pump (24) can be changed. The hydraulic control circuit (30) comprises a pressure relief valve (42) and an electronically controllable control valve (36). The aim of the invention is to ensure a prioritization of the hydraulic load while simultaneously increasing the engine load. This is achieved in that the hydraulic control circuit (30) comprises a load pressure-controlled pressure balance (38) between the pressure relief valve (42) and the control valve (36).

Description

Hydraulic arrangement

The invention relates to a hydraulic arrangement with

at least one hydraulic consumer, one

load-pressure-controlled hydraulic pump, a hydraulic tank and one connected to the hydraulic consumer

hydraulic control circuit, with which one of the

Hydraulic pump funded flow is variable, wherein the hydraulic control circuit comprises a pressure relief valve and an electronically controllable control valve. Furthermore, the invention relates to an agricultural vehicle with such a hydraulic arrangement.

It is known to hydraulic arrangements

agricultural vehicles, such as tractors, harvesters or other self-propelled machines, or to equip construction equipment with a hydraulic control circuit which is designed and connected to a hydraulic circuit or to a hydraulic system or to a hydraulic consumer, that in certain operating conditions, in particular At low engine speeds and / or low engine loads, a funded by a load pressure controlled hydraulic pump volume flow is increased. In particular, such hydraulic control circuit serve to temporarily increase the engine load artificially to a required for a burn-out of a diesel particulate filter exhaust gas temperature

to reach. An increase in engine load then takes place in that a higher volume flow is conveyed by the hydraulic pump and correspondingly a higher engine load is called up at the engine. Such hydraulic control circuits for engine load increase usually include a pressure relief valve, which in

Connection to one of an electronic control unit controlled switching valve is switchable, so that a

additional volume flow dissipated and thus one

Volumetric flow increase is achieved at the hydraulic pump, wherein the connection of the pressure relief valve or the control of the switching valve is carried out when the electronic control unit provides a corresponding signal indicative of an excessively low exhaust gas temperature at the diesel particulate filter. Said hydraulic control circuit is designed such that an activation of the control circuit, i. a connection of the pressure relief valve or a control of the switching valve, the hydraulic supply hydraulic priority systems, such as a hydraulic brake system, hydraulically assisted steering, etc., is not affected. However, it is usually different in hydraulic secondary systems or consumers. When connecting the pressure relief valve or

Control of the switching valve is the hydraulic supply of a connected to the hydraulic arrangement

Secondary consumer, be it an additional hydraulic motor, a hydraulic hitch with power lift, a

Front loader or the like, interrupted or temporarily suspended. A prioritization of hydraulic

Secondary systems or the hydraulic secondary consumer does not take place, which can lead to sudden power fluctuations or temporary suspension of the secondary system.

The object underlying the invention is seen therein, a hydraulic arrangement of the type mentioned

specify that overcomes the aforementioned problems.

The object is achieved by the teaching of

Patent claims 1 and 7 solved. Further advantageous Embodiments and developments of the invention will become apparent from the dependent claims.

According to the invention, a hydraulic arrangement of the type mentioned is designed such that the hydraulic

Control circuit between pressure relief valve and control valve comprises a load pressure-controlled pressure compensator. The control valve downstream load pressure-dependent pressure compensator causes a priority control for a hydraulic consumer

(Secondary consumer), so that it can be operated independently of an increase in the engine load or a volume flow promotion of the hydraulic pump, without that

Power fluctuations or dropouts occur.

The load pressure control of the pressure balance and the hydraulic line can be done by a connected to the hydraulic load load pressure line, which at the consumer

prevailing operating pressure reports or signals. The load pressure line may be connected to a first control pressure line which leads to the pressure balance and acts on one side with a pressure prevailing in the load pressure line. By the pressurization of the first

Control pressure line, the pressure compensator can be urged in a corresponding first direction.

The proportional control valve and the pressure compensator can be connected to each other via a first hydraulic line, wherein a second control pressure line branches off from the first hydraulic line to the pressure compensator. The second control pressure line causes a pressurization of the pressure compensator on the opposite side of the above-mentioned first control pressure line. By the pressurization of the second control pressure line the pressure compensator can be urged in a corresponding second direction opposite the first direction. So the pressure balance is on the one hand by one in the first

Control pressure line and on the other hand by a pressure prevailing in the second control pressure line in a certain

Position forced or brought, on the one hand the

Load pressure and on the other hand, the voltage applied to the load, generated by the hydraulic pump, supply pressure to the pressure compensator is applied.

The pressure compensator and the pressure relief valve are connected via a second hydraulic line. Furthermore, a third

Control pressure line to be provided with the

Load pressure line is connected. In order to avoid a flow through the load pressure line in the direction of the second hydraulic line and thus avoiding the pressure balance, in the third control pressure line in the direction of the second

Hydraulic line closing check valve may be arranged. It is thereby ensured that in the first control pressure line always build a pressure in the direction of the pressure compensator and this is not in the direction of the second

Hydraulic line can break down.

In order to achieve a stepless priority control, the pressure compensator can be designed as a proportional valve.

The electronically controllable control valve can also be designed as a proportional control valve, whereby an on demand volume flow increase can be achieved. In addition to a lack of priority control for one

hydraulic (secondary) consumers are known in the art hydraulic control circuits usually with equipped with a simple switching valve. When activating a control circuit with a simple switching valve is a demand-independent, fixed set

Volume flow discharge, whereby an engine load increase takes place, which is necessary for the exhaust gas temperature increase degree

can be exceeded and unnecessarily consumed or wasted energy and fuel. By a as

On the other hand, a proportional control valve designed control valve, a metered and thus demand-controlled

Volumetric increase, whereby the above

Disadvantages can be overcome. Nevertheless, it is alternatively conceivable, while maintaining the priority control, instead of the proportional control valve to arrange a simple switching valve, which only an opening and a

Closed position (two end positions, no intermediate positions), in which case, as mentioned above, no demand-driven increase in volume flow can take place.

A hydraulic arrangement according to the above embodiments may be arranged in an agricultural vehicle.

In this regard, it is conceivable such an arrangement also on a construction machine or at another

Provide work vehicle. The vehicle has a

Internal combustion engine, in particular diesel engine and an electronic control unit. The electronic control unit is designed such that a control of the

Control valve can be done by appropriately generated control signals, the control signals depending on certain operating conditions can be generated on the vehicle. Furthermore, the hydraulic pump can be indirect or

be driven directly from the engine, ie it can be a direct connection to the engine crankshaft or a be provided indirect connection. Furthermore, a transmission gear can be interposed or the

Internal combustion engine feed a generator, which in turn drives an electric motor for driving the pump.

The internal combustion engine may be connected to a diesel particulate filter, by means of which the exhaust gas flowing from the internal combustion engine can be cleaned. Of the

The diesel particulate filter may include means for burning out filtered diesel particulates to clean the diesel particulate filter. In this regard, a sensor connected to the electronic control unit can also be provided, via which the exhaust gas temperature,

Preferably, at the inlet of the diesel particulate filter, can be detected and depending on the electronic control unit, a control signal for controlling the control valve of the

generated by hydraulic arrangement.

The vehicle may further include a hydraulically operated transmission and an oil temperature of the transmission sensing and connected to the electronic control unit sensor, wherein the control valve in response to a signal of the sensor or in dependence on the oil temperature is controlled. For example, this can be done an oil temperature at cold operating temperatures or efficiency optimization of a transmission.

The vehicle may further include a drag torque of

Internal combustion engine sensing sensor or other that

Drag torque of the internal combustion engine detecting means

contain, wherein the control valve in response to a signal of the sensor or the means or in dependence on the drag torque of the internal combustion engine can be controlled. About appropriate signals of the sensor or the drag torque detecting means, such as operating variables

Reflect engine speed, speed, torque, etc., the drag torque can be detected on the engine and changed or controlled or controlled over the implemented in the hydraulic system control. The

Drag torque can thus be incorporated as a control variable in the control of the hydraulic arrangement, for example, an optimal engine braking in certain operating conditions

bring about. This means that during a coasting operation of the internal combustion engine, ie in an operating state in which a braking torque from the internal combustion engine to a

Powertrain of the vehicle is exercised, the

Hydraulic arrangement according to the invention can be used or used to optimize this push operation.

Reference to the drawing, which shows an embodiment of the invention, the invention and further advantages and advantageous developments and refinements of the

Invention described in more detail and explained.

It shows:

Fig. 1 is a schematic circuit diagram of a

inventive hydraulic arrangement and

2 is a Schamtische side view of a vehicle with a hydraulic arrangement of Figure 1.

FIG. 1 shows a system for priority-controlled and

Demand-oriented power increase of an internal combustion engine an agricultural vehicle. The system comprises a hydraulic arrangement 10 for an agricultural

Vehicle 12 in the form of a tractor (see Figure 2), and associated therewith, arranged on the vehicle 12 components, in particular an electronic control unit 14, a

Temperature sensor 16, an internal combustion engine 18, a

Diesel particulate filter 20, as well as connected to the engine 18 drive gear unit 22, in particular a hydraulically operated transmission.

The hydraulic arrangement 10 comprises a load-pressure-controlled hydraulic pump 24, which is provided by the

Drive transmission unit 22 is driven and drivingly connected thereto via the internal combustion engine 18. The

Hydraulic pump is as load pressure controlled (variable)

Adjusted pump formed, which can change their delivery volume at a constant or variable delivery speed due to a changing load pressure signal.

The hydraulic assembly 10 further includes a

Hydraulic consumers 32 may be included on the vehicle 12, which are not shown in detail here and primarily, ie independent of the hydraulic consumer 28 and independent of a change in volume flow can be supplied by the hydraulic control circuit 30, from the hydraulic pump 24 and can be connected to the hydraulic tank 26. Other hydraulic consumers 32 may, for example, a hydraulic brake system, a hydraulic suspension, a hydraulic steering or other

be hydraulic supply of actuators. The hydraulic circuit 30 is connected to and includes a hydraulic supply line 34

connected, electronically controllable

Proportional control valve 36, designed as a proportional valve pressure compensator 38, a proportional control valve 36 and the pressure compensator connecting first hydraulic line 40, a pressure relief valve 42 and the pressure compensator 38 with the

The hydraulic circuit 30 is further connected to a drain line 46 which leads from the pressure relief valve 42 in the hydraulic tank 26. Furthermore, the hydraulic circuit 30 is connected to a load pressure line 48 (load-sensing line), which is a load pressure of the hydraulic consumer 28 to

Control of the pressure compensator 38 and the hydraulic pump 24 supplies. In this regard, a first control pressure line 50 is provided, which connects the pressure compensator on a pressure side with the load pressure line 48. On the opposite pressure side of the pressure compensator 38 via a second

Control pressure line 52 connected to the first hydraulic line 40. A third control pressure line 54 connects the load pressure line 48 with the second hydraulic line 44, wherein in the third control pressure line 54 in the direction of the second hydraulic line 44 closing check valve 56 is arranged. The pressure relief valve 42 is normally closed and is opened via a further control pressure line 58 connected to the second hydraulic line 44. The control valve 36 is normally closed by a spring 60 and is controlled by one of the electronic

Control unit 14 generated control signal on. The pressure compensator 38 is replaced by a spring 62 in a

Biased middle position and by the in the first or second control pressure line 50, 52 urged pressure in one of the pressure difference corresponding position.

The hydraulic consumer is here as one

Secondary consumers represented, i. hydraulic

Primary consumer, e.g. a hydraulic brake system or a hydraulically assisted steering on the vehicle 12 are not shown. The hydraulic consumer may be, for example, a hoist for a front loader 64, to

Power lift on a three-point hitch 66 or about a 12 arranged on the vehicle hydraulic motor (not shown) act. Also other hydraulically operated

Components or devices used in the vehicle or on the

Vehicle 12 can be arranged, should be understood by the term secondary consumers (for example

Fronthitch, Mähvorsatz etc.).

Under normal operating conditions, the engine 12 of the vehicle 12 is used to retrieve engine powers in which one sufficient to burn out the diesel particulate filter 20

Exhaust gas temperature prevails. However, should this temperature not be reached due to low engine load operation (low speed vehicle operation and / or low power output) in the exhaust, especially in the area of the diesel particulate filter, the burnout process may not be fully accomplished or will not occur. In this case, an artificial engine load increase according to the invention can be carried out, wherein the same vehicle operating state can be maintained. In this regard, the arranged on the diesel particulate filter 20 temperature sensor 16 signals the electronic

Control unit 14 is below an adjustable threshold (burnout) exhaust gas temperature (preferably at Inlet of the diesel particulate filter 20) whereupon the electronic control unit 14 generates a control signal for controlling the control valve 36. By controlling the

Control valve 36 is an additional hydraulic

Volume flow (leakage current) retrieved and over the open

(controlled) control valve 36, the pressure compensator 38 and the opening pressure relief valve 58 passed into the hydraulic tank 26. At the same time, an increased load pressure is signaled via the load pressure line 48, whereupon, on the one hand, the pressure balance 38 (via the adjacent control pressure lines 50, 52) adjusts and, on the other hand, the delivery volume to the hydraulic pump 24

Is increased (via the applied there load pressure line 48). The increase of the delivery volume at the adjustable

Hydraulic pump 24 leads at a constant delivery speed or at constant engine speed to an increased power output on the engine 18. The engine load is increased. This in turn generates a temperature increase in the exhaust gas to above the predetermined threshold (burnout), so that burning out of the diesel particulate filter can take place. As soon as the burn-out process is completed, a corresponding message is issued (not shown here)

Sensor means) to the control unit 14, whereupon a

corresponding control signal for closing the switching valve 36 is generated. By the downstream of the switching valve 36 arranged pressure compensator 38 ensures that a

Volume flow increase to the extent that on the one hand, the hydraulic load 28 remains unchanged operation

continue (prioritization of the secondary consumer), and on the other hand, the required increase in the output of the engine 18 (engine load increase) to adapt the exhaust gas temperature to that for the Ausbrennvorgang the

Diesel particulate filter 20 required temperatures achieved becomes. By designed as a proportional valve control valve 36, a control thereof by the electronic control unit 14 is demand-controlled, so only to the extent required by the vehicle operating condition.

Even if the invention only by means of a

In the light of the above description and the drawing, many different alternatives, modifications and variants which fall within the scope of the present invention will be apparent to those skilled in the art. Thus, for example, such a hydraulic arrangement 10 may be designed such that via a sensor 14 ^λ a

Oil temperature of a hydraulic load, such as a hydraulically operated transmission 22, monitored and controlled analogously to the control of the exhaust gas temperature, or as a control variable analogous to the control of the hydraulic

Arrangement 10 flows to counteract fluctuations in the operating temperature of the hydraulic consumer or to keep this to an optimum operating value. Further

Embodiments of an inventive hydraulic assembly 10 can be such that a suitable sensor 14 ^{λ λ} or other means operating variables (speed,

Speed, torque, etc.) and from it

Drag torque on the engine 18 is determined. This can then be controlled analogously to the control of the exhaust gas temperature, or incorporated as a control variable in the control of the hydraulic assembly 10, for example, an optimal engine braking in certain operating conditions, for example in a

Overrun operation of the internal combustion engine 18 to obtain, or in these operating conditions, the engine braking or the

Optimize push operation.

Claims

claims

Hydraulic arrangement (10) with at least one

hydraulic load (28), a load pressure controlled hydraulic pump (24), a hydraulic tank (26) and connected to the hydraulic consumer (28)

hydraulic control circuit (30), with which a of the hydraulic pump (24) conveyed volume flow is variable, wherein the hydraulic control circuit (30) a

Pressure relief valve (42) and an electronically controllable control valve (36), characterized in that the hydraulic control circuit (30) between pressure relief valve (42) and control valve (36) is a load pressure controlled

Compression balance (38) includes.

Hydraulic arrangement (10) according to claim 1, characterized in that a load pressure line (48) is included, from which a first control pressure line (50) branches off to the pressure compensator (38).

Hydraulic arrangement (10) according to claim 1 or 2, characterized in that a first hydraulic line

(40) which connects the control valve (36) and the pressure compensator (38), wherein a second

Control pressure line (52) from the first hydraulic line

(40) branches off to the pressure compensator (38).

4. Hydraulic arrangement (10) according to claim 2 or 3,

characterized in that the pressure compensator (38) and the pressure relief valve (42) connecting second Hydraulic line (44) is connected, which via a third control pressure line (54) to the load pressure line (48) is connected, wherein in the third

Control pressure line (54) one in the direction of the second

Hydraulic line (44) closing the check valve (56) is arranged.

5. Hydraulic arrangement (10) according to one of the preceding claims, characterized in that the pressure compensator

(38) is designed as a proportional valve.

6. Hydraulic arrangement (10) according to one of the preceding claims, characterized in that the control valve

(36) is designed as a proportional control valve.

7. Agricultural vehicle (12), with one

Internal combustion engine (18), an electronic

Control unit (14), and a hydraulic arrangement (10) according to one of the preceding claims, characterized in that the hydraulic pump (28) directly or indirectly from the internal combustion engine (18)

drivable and the control valve (36) of the

electronic control unit (14) is controllable.

8. Agricultural vehicle (12) according to claim 7,

characterized in that a diesel particulate filter (20) and an exhaust gas temperature or

Diesel particulate filter temperature sensing and with the electronic control unit (14) connected sensor (16) is included, wherein the control valve (36) in

Dependence on a signal of the sensor (16) or in Dependence on the exhaust gas temperature or

Diesel particle filter temperature is controllable.

9. Agricultural vehicle (12) according to claim 7,

characterized in that a hydraulically operated transmission (22) and an oil temperature of the transmission (22) detecting and connected to the electronic control unit (14) sensor (14 ^λ ) is included, wherein the control valve (36) in response to a signal of the Sensor (14 ^λ ) or in dependence on the oil temperature can be controlled.

10. Agricultural vehicle (12) according to claim 7,

characterized in that a sensor (14 ^{λ λ} ) which detects a drag torque of the internal combustion engine (18) or the drag torque of the internal combustion engine (18) are detected, the control valve (36) being dependent on a signal from the sensor (14 ^{λ λ} ). or the means or in dependence on the drag torque of the internal combustion engine (18) can be controlled.