阅读说明：本技术 用于具有泵和多个阀的液压系统的致动方法以及液压系统 (Actuation method for a hydraulic system having a pump and a plurality of valves, and hydraulic system ) 是由 魏云帆 于 2020-03-25 设计创作，主要内容包括：本发明涉及一种用于致动机动车辆的致动装置所用的液压系统(1)的方法,其中,液压系统(1)具有泵(2)、多个阀(3a、3b、3c),多个阀各自布置在连接至泵出口(4)的系统导轨(5)与液压消耗器(6a、6b、6c)之间,其中,泵(2)根据液压消耗器(6a、6b、6c)的现有总能量要求在常规操作与增强操作之间切换,其中,在常规操作中,以规则的时间间隔确定系统导轨(5)中的现有系统压力,并计算系统导轨(5)的目标压力,并且基于目标压力建立上压力阈值和下压力阈值,其中,泵(2)在系统压力低于下压力阈值时被驱动并且在系统压力高于上压力阈值时被关闭,并且其中,在增强操作中,泵(2)被持久地驱动,并且一旦系统压力达到或超过阈值,形成为压力控制阀的阀(3a、3b、3c)中的每个阀根据相应的液压消耗器(6a、6b、6c)的单独能量要求而至少周期性地操作。本发明还涉及一种液压系统(1)。(The invention relates to a method for actuating a hydraulic system (1) for an actuating device of a motor vehicle, wherein the hydraulic system (1) has a pump (2), a plurality of valves (3a, 3b, 3c) which are each arranged between a system guide rail (5) connected to a pump outlet (4) and a hydraulic consumer (6a, 6b, 6c), wherein the pump (2) is switched between a normal operation and a boost operation as a function of an existing total energy requirement of the hydraulic consumer (6a, 6b, 6c), wherein in the normal operation an existing system pressure in the system guide rail (5) is determined at regular time intervals and a target pressure of the system guide rail (5) is calculated and an upper pressure threshold value and a lower pressure threshold value are established on the basis of the target pressure, wherein the pump (2) is driven when the system pressure is below the lower pressure threshold value and is closed when the system pressure is above the upper pressure threshold value, and wherein in the boost operation the pump (2) is permanently driven and each of the valves (3a, 3b, 3c) formed as pressure control valves is at least periodically operated in accordance with the individual energy requirements of the respective hydraulic consumer (6a, 6b, 6c) once the system pressure reaches or exceeds a threshold value. The invention also relates to a hydraulic system (1).)

1. Method for actuating a hydraulic system (1) for an actuating device of a motor vehicle, wherein the hydraulic system (1) has a pump (2), a plurality of valves (3a, 3b, 3c), which valves (3a, 3b, 3c) are each arranged between a system guide (5) and a hydraulic consumer (6a, 6b, 6c), which system guide is connected to a pump outlet (4), wherein the pump (2) is switched between a normal operation and a boost operation depending on the existing total energy requirement of the hydraulic consumers (6a, 6b, 6c),

wherein, in normal operation, an existing system pressure in the system rail (5) is determined at regular time intervals, and a target pressure for the system rail (5) is calculated, and an upper pressure threshold and a lower pressure threshold are established based on the target pressure, wherein the pump (2) is driven when the system pressure is below the lower pressure threshold, and the pump is switched off when the system pressure is above the upper pressure threshold,

and wherein in the boost operation the pump (2) is permanently driven and each of the valves (3a, 3b, 3c) formed as pressure control valves is at least periodically operated in accordance with the individual energy requirements of the respective hydraulic consumer (6a, 6b, 6c) as soon as the system pressure reaches or exceeds a threshold value.

2. Method according to claim 1, characterized in that, at least in normal operation, the actuation of the valves (3a, 3b, 3c) is decoupled from the actuation of the pump (2).

3. Method according to claim 1 or 2, characterized in that it is determined that the total power requirement for switching between the normal operation and the boost operation corresponds to the total volumetric flow requirement of all consumers (6a, 6b, 6c), wherein boost operation is initiated when the total volumetric flow requirement is above an upper volumetric flow threshold and normal operation is initiated when the total volumetric flow requirement is below a lower volumetric flow threshold.

4. Method according to claim 3, characterized in that the upper and/or lower volume flow threshold is formed by a fixed constant or a temperature-dependent and/or system pressure-dependent variable.

5. Method according to claim 3 or 4, characterized in that the total volume flow requirement is calculated based on the sum of a first partial volume flow requirement determined by a first hydraulic consumer (6a, 6b, 6c) and a second partial volume flow requirement determined by at least one further second hydraulic consumer (6a, 6b, 6c), wherein the specific partial volume flow requirement is determined based on a pressure-volume function stored in software.

6. Method according to one of claims 1 to 5, characterized in that in both normal operation and boost operation, a maximum system voltage is applied to an electric motor (7) driving the pump (2).

7. Method according to claims 1-6, characterized in that a pressure relief valve (11) is arranged in the system rail (5).

8. Method according to one of claims 1 to 7, characterized in that the target pressure is the maximum value from the set of target consumer pressures required for a specific individual consumer (6a, 6b, 6 c).

9. Method according to one of claims 1 to 8, characterized in that the upper pressure threshold is calculated using a first load factor based on the target pressure and/or the lower pressure threshold is calculated using a second load factor based on the target pressure, wherein at least one of the load factors is a fixed constant or a temperature-dependent and/or system pressure-dependent variable.

10. A hydraulic system (1) for a motor vehicle, wherein the hydraulic system (1) is designed to perform a method according to one of claims 1 to 9.

Technical Field

The present invention relates to a method for actuating a hydraulic system for an actuating device of a motor vehicle, such as a car, truck, bus or other commercial vehicle. The actuating device is preferably a clutch actuating device having an actuating effect on a clutch of a drive train of the motor vehicle. The invention also relates to a hydraulic system designed to carry out the method.

Background

A general method for actuating at least one clutch is known from the prior art, for example from DE 102014208182 a 1.

Further prior art of the general type can be seen in connection with fig. 4. The drive train system 1', which can be identified primarily here, has a pressure accumulator which is kept at a relatively high pressure level during operation by means of a hysteresis control. The actuation of the pump can be realized in a relatively simple manner using a so-called two-point controller, and the actuation of the individual valves can be separated from the pump control. However, this system has the disadvantage that, owing to the existing pressure accumulators, even in those operating states in which such a high pressure is not required, a relatively high pressure is provided, since the individual hydraulic consumers K0, K1, K2 may operate at a significantly lower pressure. As a result, a relatively large part of the energy previously supplied into the accumulator is lost again at the valve edge of the valve.

In addition, there are in principle hydraulic devices without an accumulator, but these systems generally have the disadvantage that they have a relatively complex structure. The pump actuation must also be coordinated as precisely as possible with the valve actuation to avoid any limitation on the drive performance.

Disclosure of Invention

The object of the present invention is therefore to remedy the disadvantages known from the prior art and to provide an actuation strategy that is as simple and powerful as possible for a structure that is as simple as possible of the hydraulic system.

According to the invention, this is achieved by the subject matter of claim 1. Accordingly, a method for actuating a hydraulic system for an actuating device of a motor vehicle is claimed, the hydraulic system having a pump and a plurality of valves, each of which is arranged between a system guide rail and a hydraulic consumer, the system guide rail being connected to the pump outlet. The pump switches between normal operation and boost operation in accordance with the existing total power requirement of the hydraulic consumer (determined at regular time intervals). In normal operation, determining an existing system pressure in the system rail at regular time intervals and calculating a target pressure for the system rail; an upper pressure threshold and a lower pressure threshold are also established based on the target pressure, the pump is driven when the system pressure is below the lower pressure threshold, and the pump is turned off when the system pressure is above the upper pressure threshold. However, in boost operation, the pump is permanently driven and each of the valves designed as pressure relief valves operates at least temporarily according to the individual power requirements of a specific hydraulic consumer once the system pressure reaches or exceeds a threshold value.

This enables the hydraulic system to dispense with an accumulator and to actuate the pump and the valve as independently as possible. This simplifies the actuation of the hydraulic system considerably.

Further advantageous embodiments are claimed by the dependent claims and are explained in more detail below.

It is therefore also advantageous if, at least in normal operation, the actuation of the valve is (completely) decoupled from the actuation of the pump.

Furthermore, it is advantageous if it is determined that the total power requirement (all hydraulic consumers) of the switch between regular operation and boost operation corresponds to the total volumetric flow requirement of all consumers, the boost operation being initiated when the total volumetric flow requirement is above the upper volumetric flow threshold and the regular operation being initiated when the total volumetric flow requirement is below the lower volumetric flow threshold. This makes the hydraulic system easier to control.

In this respect, it is again advantageous if the upper and/or lower volumetric flow threshold values are formed by fixed constants or temperature-dependent and/or system pressure-dependent variables. As a result, the control method remains particularly simple.

It is also advantageous if the total volume flow requirement is calculated on the basis of the sum of a first partial volume flow requirement determined by the first hydraulic consumer and a second partial volume flow requirement determined by at least one further second hydraulic consumer, the specific partial volume flow requirement being determined using a pressure-volume function stored in software. In other variants, there are also more than two hydraulic consumers, each of which has a partial volume flow requirement. The total volume flow requirement is therefore calculated on the basis of the sum of the individual partial volume flow requirements/partial volume flow requirement values of more than two hydraulic consumers.

For as simple a pump actuation as possible, it is also beneficial if a (fixed) maximum system voltage is applied to the electric motor driving the pump, both in normal operation and in boost operation.

It is also beneficial if the pressure relief valve is incorporated/arranged in the system rail in order to achieve enhanced operation.

It is also advantageous if the target pressure is a maximum from the set of target consumer pressures required at a particular individual consumer. This allows the target pressure to be determined in a simple manner.

For the implementation of normal operation, it is also beneficial if the upper pressure threshold is calculated using a first load factor based on the target pressure and/or the lower pressure threshold is calculated using a second load factor based on the target pressure, at least one load factor being a fixed constant or representing a temperature-dependent and/or system pressure-dependent variable.

The invention also relates to a hydraulic system designed to perform a method according to the invention according to at least one of the embodiments described above.

In other words, according to the present invention, an actuation method for a hydraulic device (hydraulic system) having a pump and a plurality of valves is proposed. The basic idea is to identify "events" with high power requirements and to react to the events in a targeted manner. Based on this concept, there are two modes of operation: routine operations and event interventions (augmentation operations). In normal operation, the pump is controlled by means of a hysteresis control such that the system pressure is continuously maintained at a sufficient level. For this purpose, in a first substep a) a target pressure of the system rail is calculated. In a second sub-step b), an upper threshold value and a lower threshold value are calculated from the target pressure. In a third substep c), the pump is not driven when the system pressure is above the upper threshold value and is driven when the system pressure is below the lower threshold value. In normal operation, valve actuation is decoupled from pump actuation. Each actuation is based only on the target requirements of the respective consumer, e.g. the target pressure of the clutch. In the "event intervention" mode, the pump is driven continuously. The valve actuation remains unchanged for a while. This means that the valve power supply or applied valve voltage is maintained at the same level as when the "event intervention" mode is initiated. These valves are activated according to the target requirements of the respective consumers only after the system pressure reaches a threshold value.

Drawings

In the following, the invention will now be described in more detail with reference to the accompanying drawings.

In the drawings:

figure 1 shows a diagram of a state machine to illustrate the actuation strategy of a hydraulic system according to the invention,

fig. 2 shows a basic diagram of a hydraulic system according to the invention according to a first exemplary embodiment, which can be actuated using the actuation strategy according to fig. 1,

FIG. 3 shows a basic diagram of a hydraulic system according to the invention according to a second exemplary embodiment, which can also be actuated using the actuation strategy according to FIG. 1 and which, in contrast to the first exemplary embodiment, is equipped with a pressure-limiting valve, and

fig. 4 shows a basic representation of a hydraulic system with an accumulator designed according to the prior art.

The drawings are merely schematic in nature and are intended for an understanding of the present invention.

Detailed Description

According to a first exemplary embodiment, a hydraulic system 1 according to the invention, which is designed to carry out the method according to the invention, has the structure shown in fig. 2. Compared to the hydraulic system 1' designed according to the prior art of fig. 4, the following differences exist: in contrast to the prior art hydraulic system 1', the hydraulic system 1 according to the embodiment of the present invention does not comprise an accumulator. Branching off from the system rail 5 is a plurality of branches 10a, 10b, 10c, each of which can be connected to a hydraulic consumer 6a, 6b, 6c via an interposed valve 3a, 3b, 3c (K0, K1, K2). The valves 3a to 3c assigned to the individual consumers 6a to 6c are each embodied as a pressure regulating valve/pressure reducer. Also in a typical manner, as can be seen in connection with another hydraulic system 1 according to the invention according to the second embodiment in fig. 3, a pressure relief valve 11, which is not shown here for the sake of clarity, is incorporated in a system rail 5, which is connected to the output 4 of the pump 2.

As can also be seen from fig. 2, the hydraulic system 1 according to the invention is equipped with a pump 2 driven by an electric motor 7. Thus, the pump 2 is operated/controlled via the electric motor 7. The pump 2 is connected to a reservoir 9 via an input 8 of the pump. The output 4 of the pump 2 is directly connected to the system rail 5. The branches 10a to 10c extend from the system rail 5 to the valves 3a to 3 c. The specific branches 10a to 10c are coupled to the hydraulic consumers 6a to 6c depending on the position of the valves 3a to 3 c. Thus, in this embodiment, the first branch 10a branching off from the system rail 5 can be coupled to the first hydraulic consumer 6a via the first valve 3 a. A further second branch 10b, offset with respect to the first branch 10a along the system rail 5, may be coupled to the second consumer 6b via a second valve 3 b. A third branch 10c, which in turn is offset from the two first and second branches 10a, 10b, may be coupled to a third consumer 6c via a third valve 3 c. However, according to further embodiments, it is also possible in principle to provide less than three consumers 6a, 6b, 6c, preferably only two consumers, or more than three consumers. The consumers 6a, 6b, 6c are each part of an actuating device of a clutch (K0, K1, K2) of the drive train, for example in the form of a pressure cylinder.

The hydraulic system 1 according to the invention shown in connection with fig. 3 according to the second exemplary embodiment differs from the first exemplary embodiment only in that a pressure-limiting valve 11 is provided which is connected to the system rail 5. The remaining structure of the hydraulic system 1 according to fig. 3 corresponds to the hydraulic system 1 according to fig. 2.

According to the invention, a method for actuating the hydraulic system 1 according to the invention is achieved, which is also shown particularly well in connection with fig. 1. The method can be implemented by a hydraulic system according to fig. 2 and a hydraulic system according to fig. 3.

The pump 2 can be switched between normal operation and boost operation of the pump according to the existing total power requirement (total volume flow requirement Q _ req) of the hydraulic consumers 6a, 6b, 6 c.

The normal operation is the following operation of the pump 2: in this operation, the existing system pressure p _ sys in the system rail 5 is determined/measured at regular time intervals, and the target pressure p _ sys _ set of the system rail 5 is calculated. The target pressure p _ sys _ set is a value representing the highest pressure value to be set in the system. The target pressure p _ sys _ set is therefore the maximum value from the set of consumer target pressures required at a particular respective consumer 6a, 6b, 6 c. An upper pressure threshold p _ h and a lower pressure threshold p _ l are defined based on the target pressure p _ sys _ set. The upper pressure threshold value p _ h and the lower pressure threshold value p _ l are calculated based on additional factors representing fixed constants or temperature-dependent variables. When the system pressure p _ sys is below the lower pressure threshold p _ l, the pump 2 is driven, and when the system pressure p _ sys is above the upper pressure threshold p _ h, the pump 2 is turned off. Thus, in normal operation, the specific pressure level in the system rail 5 is always kept constant (between the lower pressure threshold value p _ l and the upper pressure threshold value p _ h). The pump 2 is switched between its off-state and on-state to maintain this pressure level.

According to the invention, an additional enhanced operation of the pump 2 is achieved. The boost operation is initiated when the total power requirement Q req exceeds a specific power requirement. The total power requirement Q req of all consumers 6a, 6b is determined as the total power requirement. The total volume flow requirement Q _ req is the sum of the partial volume flow requirements (v _1_ req, v _2_ req.) of all the individual hydraulic consumers 6a, 6b, 6c at a specific point in time. The specific partial volume flow requirement is determined using a pressure-volume function stored in software. Thus, when the total volume flow demand Q _ req is above the upper volume flow threshold Q _ h, the boost operation is enabled/normal operation is disabled, and when the total volume flow demand Q _ req is below the lower volume flow threshold Q _ l, the normal operation is enabled/boost operation is disabled. The upper and lower volumetric flow thresholds Q _ h and Q _ l are each calculated/derived from a fixed constant or temperature-dependent and system pressure-dependent variables.

In the boost operation, the pump 2 is thus permanently driven. As in the case of a pump 2 driven in normal operation, the electric motor 7 is permanently driven with a fixed (maximum) voltage value (/ system voltage) in boost operation. As soon as the system pressure p _ sys reaches or exceeds the threshold value p _ limit, each of the valves 3a, 3b, 3c, which are designed as pressure relief valves, is operated with an enhanced operation, at least temporarily, according to the individual power demand of the specific hydraulic consumer 6a, 6b, 6 c. In other words, a particular valve 3a, 3b, 3c is used for pressure reduction when the system pressure p _ sys in the system rail 5 reaches or exceeds the threshold value p _ limit.

The valves 3a, 3b, 3c are normally completely separated/independent from the actuation of the pump 2/electric motor 7.

With reference to fig. 1, typical calculations and determinations of particular values to effect handover are listed. In this figure, the motor voltage is represented by U _ motor. The system voltage is denoted U _ b. The valve flow rate to actuate a particular valve 3a, 3b, 3c is represented by I _ valve _1 (first valve 3a), I _ valve _2 (second valve 3 b). Since the specific valves 3a, 3b are implemented as pressure relief valves, the valve flows I _ valve _1, I _ valve _2 are controlled by a function (f (p _1_ set); f (p _2_ set)) according to the corresponding target pressures to be achieved at the valves 3a, 3 b. When the limit pressure value/threshold value p _ limit is reached, the actuation of the valves 3a, 3b is switched accordingly in the boosting operation. This yields the following mathematical relationship:

due to the use of conventional pressure relief valves, there is usually a mathematical relationship between the target pressure (p _1_ set; p _2_ set) according to the valve and the valve flow (I _ valve _ 1; I _ valve _ 2). This means that the pressure downstream of the valves 3a, 3b, 3c is controlled by the valve flow, i.e. I _ valve f (p _1_ set) or p _1_ set f-1(I _ valve).

In order to use the actuation strategy visualized in fig. 1, the following signal values must be determined for each time step i: 1. for a pressure interface, the pressure hysteresis control p _ h and p _ l must be mathematically determined as follows:

p_sys_set＝max(p_1_set,p_2_set,...)

p_h＝p_sys_set+dp_h

p_l＝p_sys_set+dp_l

here, dp _ h and dp _ l are stored constants, or depend on the operating temperature and p _ sys _ set according to a function/characteristic curve. The following applies:

dp_h>dp_l>0

and thus

p_h>p_l>p_sys_set

To know if an event intervention, i.e. the initiation of an enhancement operation, is necessary, Q _ req, Q _ h and Q _ l are determined mathematically:

Q_req＝(V_1_req+V_2_req+…)/(ti–ti-1)

wherein the content of the first and second substances,

V_1_req＝max[(V_1(p_1_seti)-V_1(p_1_seti-1)),0]

V_2_req＝max[(V_2(p_2_seti)-V_2(p_2_seti-1)),0]

in another preferred embodiment of the invention, Q _ req is also mathematically determined as follows:

Q_req＝(V_1_req+V_2_req+…)/(ti–ti-1)

wherein the content of the first and second substances,

V_1_req＝max[(V_1(p_1_seti)-V_1(p_1_acti)),0]

V_2_req＝max[(V_2(p_2_seti)-V_2(p_2_acti)),0]

the functions V _1 and V _2 are pressure-volume characteristics stored in software. Q _ h and Q _ l are constants or depend on the operating temperature and p _ sys _ set according to a function/characteristic curve. p _1_ seti is the target pressure of the first hydraulic consumer 6a at time point i; p _2_ seti is the target pressure of the second hydraulic consumer 6b at time i. Thus, p _1_ seti-1 is the target pressure of the first hydraulic consumer 6a at time i-1, and p _2_ seti-1 is the target pressure of the second hydraulic consumer 6b at time i-1. p _1_ act is the actual existing (actual) pressure of the first hydraulic consumer 6a at time i, and p _2_ act is the actual existing (actual) pressure of the second hydraulic consumer 6b at time i.

The motor voltage U _ b to be applied is preferably constant, but in a further variant the motor voltage is also calculated using a function/characteristic of the operating temperature and p _ sys _ set. The motor voltage U _ b to be applied can also be generated directly as a function of the pressure regulation.

In other words, the basic idea according to the invention is to identify an event with high power requirements and to react to this event in a targeted manner. Based on this concept, there are two modes of operation: routine operations and event interventions (augmentation operations).

In order to assess whether a change between regular operation and event intervention has to be made, the total volume flow requirement (Q req) of all consumers 6a, 6b, 6c is calculated. If this value is higher than the upper threshold Q _ h, the "event intervention" mode is initiated. If this value is below the lower threshold Q _ l, the "normal operation" mode is initiated.

In order to simplify actuation in normal and enhanced operation, the maximum available voltage is preferably always applied to the pump motor 7 when the pump 2 is to be driven. The system 1 preferably comprises a pressure relief valve 11 on the system rail 5, which prevents an excessively high system pressure p _ sys during an event intervention.

List of reference numerals

1 hydraulic system 2 pump 3a first valve 3b second valve 3c third valve 4 output 5 system rail 6a first consumer 6b second consumer 6c third consumer 7 electric motor 8 input 9 reservoir 10a first branch 10b second branch 10c third branch 11 pressure reducing valve