JP2000046015A - Self-diagnostic device of hydraulic circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately and automatically diagnose the failure of a control valve a variable displacement hydraulic pump which are arranged in a hydraulic circuit by utilizing the conventional device. SOLUTION: In this device for diagnosing the failure of a variable displacement hydraulic pump 10 and an electronically controlled control valve 16 which are arranged in a hydraulic circuit, a controller 30 is arranged to be changed to a normal control mode and a failure diagnostic mode. In the failure diagnostic mode, a control signal for bringing a specific change to the delivering flow of the hydraulic pump 10 is outputted while a hydraulic apparatus except for the hydraulic pump 10 is stopped, or action is performed that a pump delivery is stabled and a control signal is outputted to the control valve 16 so that specific failure diagnosing action is performed. Pump delivery pressure at this time is detected by a pressure sensor 20, and based on the detected value, the existence of the failure of the hydraulic pump 10 and control valve 16 is judged.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for automatically diagnosing a failure in a hydraulic circuit provided in a hydraulic shovel, a hydraulic crane, or the like.

[0002]

2. Description of the Related Art In general, when a failure occurs in a hydraulic circuit provided in a hydraulic excavator or the like, it is desired to quickly identify the location of the failure and to deal with the failure. Here, conventionally,
When the above-mentioned failure occurs, a measuring instrument or the like for performing the diagnosis is added to the hydraulic circuit, and then a serviceman manually performs a specific driving operation, and a state of the hydraulic circuit at this time is measured by the measuring instrument or the like. Detecting and judging the presence or absence of a failure from the value is performed.

[0003]

In the above-mentioned conventional method, since a work for adding a special measuring device or the like to the hydraulic circuit is required, a quick failure diagnosis cannot be expected, and an increase in cost cannot be avoided. Absent. In addition, in order to perform additional operations such as measuring instruments and the like, and special operation operations for failure diagnosis, it is necessary to be quite familiar with the configuration of the hydraulic circuit, and only a limited number of service personnel can deal with it. There are some defects.

As an apparatus for performing the above-described failure diagnosis, Japanese Patent Application Laid-Open No. 2-168004 discloses a hydraulic valve having a relief valve and a cut-off valve for reducing the discharge flow rate of a variable displacement hydraulic pump during the relief. In the circuit,
A system is disclosed in which the presence or absence of a failure in the relief valve or the cutoff valve is determined based on a detected value of a pump discharge pressure during the operation or a detected value of a flow rate in a relief valve return circuit. However, the discharge pressure of the hydraulic pump depends on the operation of a flow control valve that controls the flow rate of hydraulic oil discharged from the variable displacement hydraulic pump, the operation of a directional control valve that switches the flow path, or a change in the displacement of the variable displacement hydraulic pump. Since it changes, it is almost impossible to diagnose failures of the control valves and the hydraulic pump itself only by detecting the discharge pressure or the like during operation.

In view of such circumstances, the present invention utilizes an existing device to accurately detect a failure of a control valve such as a flow control valve or an electromagnetic switching valve provided in a hydraulic circuit, or a failure of a variable displacement hydraulic pump. It is an object of the present invention to provide a self-diagnosis device for a hydraulic circuit that can perform diagnosis automatically and automatically.

[0006]

As means for solving the above problems, the present invention provides an electronically controlled variable displacement hydraulic pump and a control signal for changing the discharge flow rate of the variable displacement hydraulic pump. And a controller for diagnosing a failure of the variable displacement hydraulic pump in the hydraulic circuit, the control device comprising: a control unit configured to perform a normal control operation other than the normal control mode and the variable displacement hydraulic pump. Of the variable displacement hydraulic pump can be switched to a failure diagnosis mode that outputs a control signal for giving a specific change to the discharge flow rate of the variable displacement hydraulic pump while the hydraulic device is stopped. A discharge pressure detecting means for detecting a pressure, and a control signal for actually giving the specific change in the failure diagnosis mode. That based on the pump discharge pressure is obtained and a determining failure determination means for determining whether or not the variable displacement hydraulic pump is faulty.

In this configuration, when the control means is switched to the failure diagnosis mode, a control signal for pump failure diagnosis is output from the control means, and the pump discharge pressure at the time of the output is detected. Here, if the hydraulic pump is normal, the pump discharge flow rate and the discharge pressure should change following the control signal, and the variable displacement hydraulic pump fails based on the detected value of the discharge pressure. Can be determined.

For example, a pump discharge pressure detected when a control signal is output in the failure diagnosis mode is compared with a preset discharge pressure standard value, and based on the comparison, the variable displacement hydraulic pump is faulty. It is possible to determine whether or not.

The present invention also provides a hydraulic pump, an electronically controlled control valve for controlling a flow state of hydraulic oil supplied from the hydraulic pump, and a control signal for operating the control valve. An apparatus for diagnosing a failure of the control valve of the hydraulic circuit, the control valve comprising: a control unit configured to perform a normal control operation in a normal control mode and a state in which the discharge flow rate of the hydraulic pump is constant. Discharge pressure detection means for detecting a discharge pressure of the hydraulic pump, and a failure diagnosis mode for outputting a control signal for causing a specific failure diagnosis operation to be performed. Whether the control valve is defective based on the discharge pressure detected by the discharge pressure detecting means when the control valve actually outputs the control signal for causing the failure diagnosis operation to be performed. It is obtained by a failure determination means for determining whether.

In this configuration, when the control means is switched to the failure diagnosis mode, a control signal for control valve failure diagnosis is output from the control means, and the pump discharge pressure at the time of the output is detected. Here, when the control valve is normal, the flow state of the discharge oil of the hydraulic pump and, consequently, the discharge pressure change following the control signal, so that the variable displacement hydraulic pressure is determined based on the detected value of the discharge pressure. It can be determined whether the pump has failed.

Further, according to the present invention, it is possible to make a fault diagnosis for both the variable displacement hydraulic pump and the control valve. In this case, if the control valve is diagnosed first to confirm that there is no failure, and then the failure of the variable displacement hydraulic pump is diagnosed, the latter diagnosis can be performed more appropriately.

Therefore, as an apparatus for performing such a diagnosis, the control means is provided with a normal control mode for performing a normal control operation, and a control means for controlling the control valve in a state where the discharge flow rate of the variable displacement hydraulic pump is constant. For outputting a control signal for performing the failure diagnosis operation of the above and control for giving a specific change to the discharge flow rate of the variable displacement hydraulic pump while the hydraulic equipment other than the variable displacement hydraulic pump is stopped. And a discharge pressure detecting means for detecting a discharge pressure of the variable displacement hydraulic pump, and a control valve which is actually connected to the control valve in the failure diagnosis mode. It is determined whether or not the control valve has a failure based on a pump discharge pressure detected by the discharge pressure detecting means when a control signal for performing the failure diagnosis operation is output. And, when it is determined that this control valve is normal, when the control signal for giving a specific change to the discharge flow rate of the variable displacement hydraulic pump is actually output in the failure diagnosis mode, the discharge pressure It is preferable that the apparatus further includes a failure determination unit that determines whether or not the variable displacement hydraulic pump has a failure based on the pump discharge pressure detected by the detection unit.

In the present invention, the control valve to be subjected to the failure diagnosis includes an electronically controlled flow control valve having an adjustable opening area and an electromagnetic switching valve for switching a flow path of hydraulic oil discharged from the hydraulic pump. And the like.

In the flow control valve, the control means is configured to output a control signal for continuously changing the opening area of the flow control valve as the failure diagnosis operation. If the failure determination means is configured to determine whether the flow control valve is defective based on a comparison between the detected pump discharge pressure and a preset discharge pressure standard value, the flow control valve It is possible to determine whether there is an abnormality in the static characteristics of the flow control valve, and to output a control signal for discontinuously switching the opening area of the flow control valve as the failure diagnosis operation. Means for determining a failure if the change rate of the detected value of the discharge pressure of the hydraulic pump accompanying the output of the control signal of the control means is lower than a preset speed. By configuring the failure determining means, it is possible to determine whether or not there is an abnormality in the dynamic characteristics of the flow control valve.

In the electromagnetic switching valve, the control means is configured to output a control signal for causing the electromagnetic switching valve to perform a switching operation as the failure diagnosis operation, and the control means outputs the control signal when the control signal is output. The failure determination means may be configured to determine whether or not the electromagnetic switching valve has a failure based on a comparison between the detected pump discharge pressure and a preset standard value. The failure determination means may be configured to determine that a failure has occurred when the change speed of the detection value of the discharge pressure of the hydraulic pump accompanying the output of the control signal is slower than a preset speed.

At the time of failure diagnosis in the failure diagnosis mode in each of the above devices, the control valve provided downstream of the hydraulic pump may be returned to, for example, a neutral position. By providing the operation lock means that can be switched between an unlocked state that enables the operation of the control valve and a locked state that disables the operation, in the failure diagnosis mode, by setting the operation lock means to a locked state, It is possible to avoid a disadvantage that the control valve is operated by mistake at the time of failure diagnosis. In order to perform the operation lock of the control valve, for example, the lever operation by the driver may be disabled, or the control valve may be prevented from being operated in conjunction with the operation of the driver. Good.

Further, if the control means is provided with a lock control means for switching the operation lock means to the locked state when the control means is switched to the failure diagnosis mode, the operation of the control valve is securely locked at the time of failure diagnosis. You.

[0018]

FIG. 1 shows a first embodiment of the present invention.
This will be described with reference to FIG.

The hydraulic circuit shown in FIG. 1 includes a variable displacement hydraulic pump 10 and a discharge signal can be electronically controlled by inputting a control signal to a regulator 11 thereof. The discharge port of the pump 10 is connected to a center bypass line 12 communicating with the tank. Along the center bypass line 12, hydraulic pilot switching valves (control valves) 14A and 14B and an electronic control type (in the illustrated example, an electromagnetic control hydraulic (Pilot operated type; in the present invention, it may be simply an electromagnetic operated type.) A flow control valve 16 is arranged in series.

The hydraulic pilot switching valves 14A and 14B are
A pilot pressure generated by operating an operation lever of a remote control valve (remote control valve) (not shown) is supplied, and the spool position is switched by the pilot pressure to change the flow state of hydraulic oil. Specifically, the hydraulic pilot switching valve 14A (14B) maintains the neutral position in the drawing when the pilot pressure is not supplied, and in this position, the head side chamber and the rod side chamber of the hydraulic cylinder 19A (19B) are blocked. At the same time, the discharge oil from the variable displacement hydraulic pump 10 passes through the center bypass line 12 as it is. On the other hand, when the pilot pressure is supplied to the pilot port on one side (the left side in the figure), the pilot port is switched to the left position in the figure and the hydraulic pump 10
The oil discharged from the cylinder is guided to the head side chamber of the hydraulic cylinder 19A (19B), and the rod side chamber communicates with the tank. Conversely, when the pilot pressure is supplied to the pilot port on the other side (the right side in the figure), it is switched to the right position in the figure, and the discharge oil from the hydraulic pump 10 is supplied to the rod side chamber of the hydraulic cylinder 19A (19B). And the head side chamber communicates with the tank.

The flow control valve 16 has a solenoid 17, and the flow path area (opening area) is adjusted by a control signal input to the solenoid 17.
That is, the flow control valve 16 is connected to each hydraulic cylinder 19
A, 19B are for performing bleed-off control.

In FIG. 1, reference numeral 18 denotes a main relief valve.

The center bypass line 1 between the variable displacement hydraulic pump 10 and the hydraulic pilot switching valve 14A
2 is provided with a pump pressure sensor (discharge pressure detecting means) 20 for detecting a discharge pressure of the hydraulic pump 10.
The pilot line for the hydraulic pilot switching valve 14A is provided with pilot pressure sensors 22A and 24A for detecting the pilot pressure. Similarly, the pilot line for the hydraulic pilot switching valve 14B is provided for the pilot pressure for detecting the pilot pressure. Sensors 22B and 24B are provided. And, these pressure sensors 20, 22
The detection signals A,... Are input to the controller 30.

The controller 30 can be constructed by a microcomputer or a combination of appropriate logic circuits, and includes a normal control mode for performing a normal control operation and a failure diagnosis mode (in this embodiment, the flow control valve 1).
6 and a mode for diagnosing a failure of the variable displacement hydraulic pump 10). A mode changeover switch 26 for switching the mode and a display device 27 for displaying a failure diagnosis result are connected to the controller 30. The mode changeover switch 26 and the display device 27 may be provided in a place where the hydraulic circuit is operated, for example, in a cab of a hydraulic shovel. Further, a switch for mode switching may be provided in the controller 30 itself.

The controller 30 has a control signal output unit 32, a standard value storage unit 34, and a failure determination unit 36 as shown in FIG.

In the normal control mode, the control signal output means (control means) 32 controls each of the pressure sensors 20, 22A,
.. Based on the detection signal input from
A control signal is output to the solenoid 17 and the regulator 11 to control the operation. In the failure diagnosis mode, an operation of outputting to the solenoid 17 a control signal for causing the flow control valve 16 to perform a specific failure diagnosis operation while keeping the discharge flow rate of the variable displacement hydraulic pump 10 constant,
Next, an operation of outputting to the regulator 11 a control signal for giving a specific change to the discharge flow rate of the variable displacement hydraulic pump 10 while keeping the flow area of the flow control valve 16 constant. The specific contents will be described later in detail.

When the flow rate control valve 16 is assumed to be normal in the failure diagnosis mode, the standard value memory 34 outputs a control signal to the solenoid 17 to perform a specific failure diagnosis operation. When the variable displacement hydraulic pump 10 is assumed to be normal and the value of the pump discharge pressure to be detected (that is, the discharge pressure standard value for control valve diagnosis) is to be detected, a specific change is given to the discharge flow rate. And a value of a pump discharge pressure to be detected when a control signal for the pump 11 is output to the regulator 11 (that is, a discharge pressure standard value for pump diagnosis).

The failure determination means 36 performs the following determination operation in the failure diagnosis mode. A comparison between the discharge pressure standard value for the control valve diagnosis and a discharge pressure detection value by the pressure sensor 20 when a control signal for actually causing the flow control valve 16 to perform the failure diagnosis operation is output. Based on this, it is determined whether the control valve 16 is out of order. When the flow control valve 16 is determined to be normal, the discharge pressure standard value for pump diagnosis and the control signal for actually giving a specific change to the variable displacement hydraulic pump 10 are output. Based on a comparison with the discharge pressure detection value by the pressure sensor 20, the variable displacement hydraulic pump 1
It is determined whether 0 is a failure.

Next, a specific control operation performed by the controller 30 in each mode will be described.

A) Normal control mode In this mode, the flow rate is controlled in accordance with the operation of the operating lever by the operator. Specifically, based on the pilot pressure detection signals output from the pilot pressure sensors 22A, 24A, 22B, and 24B, the operation direction and the operation amount of the operation lever are grasped, and the pressure is adjusted so that the discharge flow rate corresponding to the operation direction and operation amount can be obtained. Based on the detection signal of the sensor 20, the discharge flow rate of the variable displacement hydraulic pump 10 is feedback-controlled, and the bleed-off control is performed by appropriately adjusting the flow area of the flow control valve 16.

B) Failure Diagnosis Mode In this mode, failure diagnosis of the flow control valve 16 and the variable displacement hydraulic pump 10 is performed in the following order.

Diagnosis of Static Characteristics of Flow Control Valve 16 (FIG. 3) This diagnosis is performed in a state where the operation lever is returned and the pilot switching valves 14A and 14B, which are control valves, are maintained at the neutral position. Here, it is more preferable to provide a means for fixing the pilot switching valves 14A and 14B at the neutral position by locking the operation lever or allowing the pilot pressure oil to escape directly to the tank as described later.

In the diagnosis, a control signal for gradually (continuously) reducing the flow area (opening area) of the flow control valve 16 while maintaining the discharge flow rate of the variable displacement hydraulic pump 10 constant is maintained. Perform by outputting. Predetermined Specifically, in this embodiment, the period as shown in FIG. 3 (a), up to the time t ₁ to maximize the open area of the flow control valve 16, from time t ₁ to time t ₂ the first slope linearly decreasing the opening area, the opening area with a small second gradient than the first slope during the period from time t ₂ to time t ₃ linearly reduced eventually fully closed in Is output to the solenoid 17.

At this time, if the flow path control valve 16 is normal and performs an operation corresponding to the above control signal accurately, the value P detected by the pressure sensor 20 is indicated by a dashed line in FIG. as shown, until reaching the time t ₁ to maintain a pressure P1 corresponding to the neutral pressure loss, increase rate decreases after reaching the set pressure P2 of the main relief valve 18 gradually increases from the time t _1, the time t _{After 3 the} pressure should converge at a pressure slightly higher than the set pressure P2. That is, the value indicated by the one-dot chain line is the discharge pressure standard value for control valve static characteristic diagnosis stored in the standard value memory 34.

Therefore, the failure determining means 36 compares the standard value with the detected pressure value P which is actually detected when the control signal is being output, and determines that the difference is within a fixed end range. (Ie, when the locus of the detected pressure value falls within the mesh area of FIG. 3B), it is determined that the static characteristics are normal, and otherwise, there is a failure. Is determined. Furthermore, in the latter case,
The point of failure is specified depending on at which point the detected value P is out of the mesh area. Specifically, it is as follows.

(A) When the initial value of the detected pressure value P is greatly deviated from the pressure value P1 → It is determined that the neutral pressure loss is abnormal. (b) the time t ₁ ~t pressure detection value P for a period of ₃ judges that there is an abnormality in static stroke operation when → flow path control valve 16 which protrudes from the mesh region. (c) When the convergence value of the detected pressure value P is greatly deviated from the final value of the standard value → It is determined that the set pressure of the main relief valve 18 is abnormal.

The failure judging means 36 determines whether the diagnosis is normal or not, and if it is abnormal, determines the failure judgment item and the degree of abnormality (standard value and detected value P). Is displayed on the display device 27.

The way of changing the opening area of the flow control valve 16 in this diagnosis is not limited to that shown in FIG. 3A, and various settings can be made.

The dynamic characteristic diagnosis of the flow control valve 16 (FIG. 4) is performed, similarly to the static characteristic diagnosis, by fixing the pilot switching valves 14 A and 14 B at the neutral position and discharging the variable displacement hydraulic pump 10. This is performed by reducing the opening area of the flow control valve 16 in a state where is kept constant.
Here, instead of gradually reducing the opening area, the opening area is changed discontinuously as shown in FIG. 4A (in this embodiment, the opening area is completely closed).
Such a command signal (control signal) is output to the solenoid 17.

Here, assuming that the time t when the above-mentioned full-close command is issued is 0, when the flow path control valve 16 is normal, the detected pressure value P rapidly increases from the time of t = 0. After that, it should exhibit a characteristic of attenuating oscillation and converging at a pressure slightly higher than the relief set pressure. Therefore, the time Td required from the time t = 0 to the time when the actual pressure detection value P reaches a preset reference pressure (<relief set pressure) is measured, and when this time Td is equal to or less than a predetermined value. , It is determined that the dynamic characteristic of the flow control valve 16 is normal, and otherwise, it is determined that there is a failure.

In this embodiment, a control signal for causing the flow control valve 16 to be rapidly closed is output as a failure diagnosis operation. Conversely, the flow control valve 16 is rapidly opened. Alternatively, a control signal for performing an appropriate operation may be output.

Diagnosis of Variable Displacement Type Hydraulic Pump 10 (FIG. 5) In this diagnosis, when there is no failure in the flow control valve 16, the pilot switching valves 14A and 14B are fixed at the neutral position and the flow rate is This is performed by outputting a control signal to the regulator 11 to gradually increase or decrease the discharge flow rate of the variable displacement hydraulic pump 10 while keeping the opening area of the control valve 16 constant. Although the way of increasing or decreasing this can be set as appropriate, in this embodiment, FIG.
As shown in (a), a discharge amount command signal (control signal) that increases the discharge flow rate at a constant gradient, maintains a predetermined flow rate, and then decreases the discharge flow rate at a constant gradient is output to the regulator 11.

At this time, if the variable displacement hydraulic pump 10 is normal and performs an operation corresponding to the above control signal accurately, the value P detected by the pressure sensor 20 becomes
(B) As shown by the one-dot chain line, the change should substantially follow the discharge amount command signal. That is, the value indicated by the one-dot chain line is the standard value for pump diagnosis stored in the standard value memory 34.

Therefore, the failure determination means 36 compares the standard value with the detected pressure value P which is actually detected when the control signal is being output, and determines that the difference is within a certain fixed range. (Ie, when the locus of the detected pressure value falls within the mesh area of FIG. 3B), it is determined that the discharge flow rate characteristic of the variable displacement hydraulic pump 10 is normal, Otherwise, it is determined that there is a failure.

According to such a device, a failure diagnosis mode different from the normal control mode is provided, and in this mode, the flow control valve 16 and the variable displacement hydraulic pump 10 perform a special failure diagnosis operation. The existing pressure sensor 20
Using only the flow control valve 16 and the variable displacement hydraulic pump 1
The presence / absence of a 0 failure can be accurately determined. In particular,
In this embodiment, first, it is determined whether there is a failure in the flow control valve 16, and after confirming that there is no failure in the flow control valve 16, the failure diagnosis of the variable displacement hydraulic pump 10 is performed. Therefore, a more appropriate diagnosis can be performed than when a failure diagnosis is performed only for the variable displacement hydraulic pump 10.

However, the present invention is applicable to the case where only the failure diagnosis of the flow control valve 16 is performed or the variable displacement hydraulic pump 1
Needless to say, the present invention can be applied to a case where only the failure diagnosis of 0 is performed. In the former case, the hydraulic pump is not necessarily a variable displacement type, and may be a constant displacement type.

FIG. 6 shows a second embodiment. Here, hydraulic pilot switching valves 14A and 14B are connected in parallel to the discharge port of the variable displacement hydraulic pump 10, and a flow control valve 16 is provided between the discharge port of the variable displacement hydraulic pump 10 and the tank. Is provided. That is, the flow control valve 16 is provided with the hydraulic pilot switching valves 14A, 14B.
Although it is provided on the front side, it plays a role of performing bleed-off control similarly to the flow control valve 16 shown in the first embodiment.

In such a hydraulic circuit as well, the first
The normal control mode and the failure diagnosis mode can be executed by the operation exactly the same as the control operation shown in the embodiment.

Next, a third embodiment will be described with reference to FIGS.

The hydraulic circuit shown in FIG. 7 is similar to the hydraulic cylinder 19A for attachment shown in the first embodiment.
In addition to 19B, the left and right hydraulic motors 42A and 42B for driving a vehicle (for example, a vehicle of a self-propelled crane) are driven, and two variable displacement hydraulic pumps 10A and 10B and It has two center bypass lines 12A and 12B. Although not shown, each of the variable displacement hydraulic pumps 10A and 10B also includes a regulator for adjusting the discharge flow rate. Along with the center bypass line 12A, hydraulic pilot switching valves 40A and 14A and an electromagnetically controlled hydraulic pilot operated flow control valve 16A are arranged in series in this order, and in the center bypass line 12B, Along with this, the hydraulic pilot switching valves 40B, 14B and the electromagnetically controlled hydraulic pilot operated flow control valve 16B are arranged in series in this order.

The hydraulic pilot switching valves 14A, 14B and the flow control valves 16A, 16B are respectively the hydraulic pilot switching valves 14A, 14B shown in the first embodiment.
The control operation is completely the same as that of the flow control valve 16, and the description of the third embodiment will be omitted.

The hydraulic pilot switching valves 40A and 40B are
They are provided for controlling the rotation direction and rotation speed of the hydraulic motors 42A and 42B, respectively. Specifically, the hydraulic pilot switching valve 40A (40B) maintains the neutral position in the drawing when the pilot pressure is not supplied, and in this position, both ports of the hydraulic motor 42A (42B) communicate with the tank ( That is, the neutral-free state) and the variable displacement hydraulic pump 10A or 1A.
Center oil bypass line 1
Pass through 2A (12B). On the other hand, when the pilot pressure is supplied to any of the pilot ports, the position is switched to the left position or the right position in the drawing, and the discharge oil is supplied to the hydraulic motor 4.
Lead to one port of 2A and connect the other port to the tank.

In FIG. 7, reference numerals 18A and 18B denote main relief valves connected to the discharge sides of the variable displacement hydraulic pumps 10A and 10B, respectively.

While the center bypass line 12B is directly connected to the discharge port of the variable displacement hydraulic pump 10B, an electromagnetic switching valve is provided between the center bypass line 12A and the two variable displacement hydraulic pumps 10A, 10B. 28 are interposed. The electromagnetic switching valve 28 is connected to both hydraulic motors 4 as described in the later-described “normal control mode”.
This is provided in order to ensure the traveling straightness when at least one of the hydraulic cylinders 19A and 19B is operated while traveling while simultaneously driving the 2A and 42B.
Specifically, the solenoid-operated switching valve 28 is
In the off position (right position in the figure) where no control signal is input to a, only the discharge port of the variable displacement hydraulic pump 10A is connected to the center bypass line 12A, while the control signal is input to the solenoid 28a. In the position (left position in the figure), the discharge port of the variable displacement hydraulic pump 10B is connected to the center bypass line 12A, and the discharge port of the variable displacement hydraulic pump 10A is connected to each hydraulic pilot through a special bypass line 13. Switching valves 14A, 14B
Input port (each hydraulic pilot switching valve 14A, 14B
Is switched to the left position in FIG.
A, 19B), and a flow path that connects the two bypass lines 12A, 13 with each other via a throttle having a small opening area.

On the discharge side of each of the variable displacement hydraulic pumps 10A and 10B, pump pressure sensors (discharge pressure detecting means) 20A and 20B for detecting the discharge pressure are provided, and the hydraulic pilot switching valves 14A, 14B and 40A are provided. , 40B are also provided with a pilot pressure sensor 22 (FIG. 8) for detecting the pilot pressure. The detection signals of these pressure sensors 20 and 22 are input to the controller 30.

As in the first embodiment, the controller 30 has a normal control mode for performing a normal control operation and a failure diagnosis mode (a mode for diagnosing a failure of the electromagnetic switching valve 28 in this embodiment). 2), and includes a control signal output unit 32, a standard value storage unit 34, and a failure determination unit 36 similar to those shown in FIG.

The specific control operation performed by the controller 30 in each mode is as follows.

A) Normal Control Mode Also in this embodiment, the operation direction and the operation amount of the operation lever are grasped based on the pilot pressure detection signal output from the pilot pressure sensor 22 so that the discharge flow rate corresponding to the operation direction can be obtained. In addition, feedback control of the discharge flow rates of the variable displacement hydraulic pumps 10A and 10B based on the detection signals of the pressure sensors 20A and 20B and bleed-off control by appropriately adjusting the flow passage area of the flow control valve 16 are described. The third embodiment is similar to the first embodiment, but additionally, in the third embodiment, on / off switching control of the electromagnetic switching valve 28 is performed according to the operation state.

First, when only the attachment is driven by the hydraulic cylinders 19A and 19B, or when only the vehicle is driven by driving the hydraulic motors 42A and 42B, the electromagnetic switching valve 28 is turned off. That is, the position is switched to the right position in FIG. Thereby, the discharge oil of the variable displacement hydraulic pump 10A is supplied only to the hydraulic motor 42A or the hydraulic cylinder 19A on one side, and the discharge oil of the variable displacement hydraulic pump 10B is supplied to the hydraulic motor 42B or the hydraulic cylinder 19B on the other side. Only supplied to. Therefore, in order to control the supply flow rate to the hydraulic motor 42A or the hydraulic cylinder 19A, the discharge flow rate of the variable displacement hydraulic pump 10A and the flow passage area of the flow control valve 16A may be adjusted. In order to control the supply flow rate, the discharge flow rate of the variable displacement hydraulic pump 10B and the flow area of the flow control valve 16B may be adjusted.

However, when the hydraulic cylinder 19A or the hydraulic cylinder 19B is operated during traveling, for example, the hydraulic motors 42A and 42B
When the hydraulic cylinder 19A is operated in a state where the hydraulic oil is supplied at a flow rate equivalent to the above, the hydraulic motor 42A is supplied by an amount corresponding to the supply of the hydraulic oil to the hydraulic cylinder 19A.
When the left and right operation levers are operated by the same amount, the rotational speed on the hydraulic motor 42B side wins and turns, resulting in an inconvenience. Therefore, in such a case, the controller 30 outputs a control signal to the solenoid 28a to switch on the electromagnetic switching valve 28. That is, the position is switched to the left position in the figure. As a result, the discharge oil of the variable displacement hydraulic pump 10A is mainly supplied to the hydraulic cylinder 19A or 19B through the bypass line 13.
Hydraulic oil is supplied to the 2A and 42B at the same flow rate from the variable displacement hydraulic pump 10B. Therefore, regardless of the operation of the hydraulic cylinders 19A and 19B, the straightness of traveling by driving the hydraulic motors 42A and 42B is ensured.

B) Failure Diagnosis Mode In this mode, failure diagnosis of the electromagnetic switching valve 28 is performed in the following manner.

First, in the same manner as described in the first embodiment, each of the hydraulic pilot switching valves 14A, 14B, 4
2A and 42B are maintained at the neutral position, the discharge flow rates of the variable displacement hydraulic pumps 10A and 10B are kept constant, and the solenoid 28a of the electromagnetic switching valve 28 is turned off. (Opening area) is reduced to make it almost fully closed (time ta in FIG. 9). Thereafter, the solenoid 28a is turned on (time tb in the figure), and is turned off after a certain time has passed (time tc in the figure).

At this time, if the electromagnetic switching valve 28 is normal and performs an operation corresponding to the above control signal accurately, the value P detected by the pressure sensor 20A becomes as shown by the lower curve in FIG. During a period from the time ta to tb, the pressure should be maintained substantially equal to the set pressure of the main relief valve 18A, rapidly dropping from the time tb, and rising rapidly from the time tc. That is, the value indicated by this curve is the standard value for diagnosis of the electromagnetic switching valve stored in the standard value memory 34.

Therefore, the failure determination means 36 compares the standard value with the detected pressure value P which is actually detected when the control signal is being output, and determines that the difference is within a fixed end range. Is determined to be normal, the electromagnetic switching valve 28 is determined to be normal, otherwise, it is determined that there is a failure. Then, the display unit 27 displays the result of the determination and the degree of the failure (the magnitude of the difference between the standard value and the detected value) when the failure is determined.

It is to be noted that, instead of the failure judgment based on the comparison between the standard value and the detected value, for example, the falling speed of the detected pressure value P from the time tb or the rising speed of the detected pressure value P from the time tc is constant. Solenoid switching valve 2
8 may be determined to be faulty.

As described above, the control valve to be diagnosed in the present invention can be widely applied to a control valve whose pump discharge pressure changes by its operation regardless of whether it is a flow control valve or a switching valve. It is. For example, the present invention can also be applied to failure diagnosis of a flow control valve for performing meter-in control or meter-out control, an electromagnetic switching valve for performing merging switching, and the like.

In each of the above embodiments, when performing a failure diagnosis, the control valves (hydraulic pilot switching valves 14A, 14B in the illustrated example) on the downstream side of the hydraulic pump 10 are used.
) Is maintained in the neutral position, but is switched between an unlocked state that enables operation of the control valve and a locked state that disables the control valve so that the control valve is not accidentally operated from the neutral position during the failure diagnosis. It is preferable to provide a lock switching means so as to switch the lock switching means to a locked state at the time of failure diagnosis.
To disable the operation of the control valve, the operation of the control lever for operating the control valve may be locked, or the control valve may be prevented from being operated in conjunction with the operation lever. You may. FIG. 10 shows the latter example.

In the figure, 50 is the main hydraulic pump 10
It is a pilot hydraulic pump driven in conjunction with
A remote control valve 52 is provided between the pilot hydraulic pump 50 and the pilot ports 14a and 14b of the hydraulic pilot switching valve 14. The remote control valve 52 is provided with a spool 5 corresponding to each pilot port 14a, 14b.
4A and 54B, and an operation lever (not shown), and when the operation lever is operated, the spool 54A or 54B corresponding to the operation direction strokes by an amount corresponding to the operation amount, thereby Spool 54A
(Or 54B), that is, the pilot pressure input to the pilot port 14a (or 14b) changes.

In the figure, reference numeral 56 denotes a main relief valve for a pilot hydraulic circuit.

Further, in this circuit, an electromagnetic switching valve (lock switching means) 58 is provided between the hydraulic pump 50 and the remote control valve 52. This electromagnetic switching valve 58
Is configured to shut off the supply of hydraulic oil from the hydraulic pump 50 to the remote control valve 52 when the solenoid is off, and to allow the supply of hydraulic oil only when the solenoid is on.

The solenoid 30 of the electromagnetic switching valve 58 is provided with the controller 30 described in each of the above embodiments. The controller 30 is connected to a changeover switch 60 for switching between a normal control mode and a failure diagnosis mode. Have been. The changeover switch 60 performs a switching operation in conjunction with operation of a mode switching operation lever provided in, for example, a cab. And the controller 3
When the changeover switch 60 is on, the solenoid switch of the electromagnetic switching valve 58 is turned on while the changeover switch 60 is on, and the solenoid of the electromagnetic changeover valve 58 is turned on.
Switching to the above-described failure diagnosis mode and the electromagnetic switching valve 5
8 is turned off.

In such a configuration, the changeover switch 6
When 0 is switched on and the normal control mode is selected, supply of hydraulic oil from the hydraulic pump 50 to the remote control valve 52 is permitted by turning on the solenoid of the electromagnetic switching valve 58. A pilot pressure corresponding to the operation direction and the operation amount of the operation lever of the remote control valve 52 is supplied to the hydraulic pilot switching valve 14, and thereby the actuator (the hydraulic cylinder 19 in the illustrated example) is driven. On the other hand, when the changeover switch 60 is turned off and the failure diagnosis mode is selected, the solenoid of the electromagnetic switching valve 58 is boiled, so that the supply of the hydraulic oil from the hydraulic pump 50 to the remote control valve 52 is cut off. Since the hydraulic oil is directly released to the tank through the relief valve 56, the pilot pressure does not rise even if the operating lever is operated, and the hydraulic pilot switching valve 14 is maintained at the neutral position (that is, the hydraulic pilot switching valve 14 is locked in an inoperable state). Is done). Therefore,
Even if the operation lever is operated by mistake during the failure diagnosis, the operation of the hydraulic pilot switching valve 14 is automatically prevented from being operated, and a good failure diagnosis operation is guaranteed.

The switching of the lock switching means is not performed by the control signal of the controller 30, but may be performed manually by the driver according to the control mode. Further, if another hydraulic device, a control valve, or the like is connected to a position between the hydraulic pump 50 and the electromagnetic switching valve 58 (for example, the position of a point A in FIG. 10), the electromagnetic switching valve 58
Can be operated by the hydraulic pump 50 even when is turned off.

In such an operation lock, a control valve (that is, a valve that changes the flow state of hydraulic oil downstream of the hydraulic pump in response to an operation of a driver or the like) is a hydraulic pilot switching valve as described above. Not only in some cases, but also when the control valve is composed of an electromagnetic switching valve or a manual switching valve, etc. Can be prevented.

[0075]

As described above, according to the present invention, the control means of the hydraulic circuit can be switched between the normal control mode and the failure diagnosis mode. In the failure diagnosis mode, the discharge flow rate of the variable displacement hydraulic pump is changed. Alternatively, a special control signal for operating the control valve is output, and the presence or absence of a failure is determined based on the pump discharge pressure detected at this time. With the configuration, there is an effect that a failure of a control valve or a variable displacement hydraulic pump provided in the hydraulic circuit can be accurately and automatically diagnosed.

[Brief description of the drawings]

FIG. 1 is a diagram showing a hydraulic circuit according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a functional configuration of a controller provided in the hydraulic circuit.

3A is a graph showing a time change of a static characteristic diagnosis opening area command signal output from the controller to the flow control valve in the failure diagnosis mode, and FIG. 3B is set corresponding to the signal; 5 is a graph showing a standard value and an allowable range of a pump discharge pressure.

4A is a graph showing a time change of an opening area command signal for dynamic characteristics diagnosis output from the controller to the flow control valve in the failure diagnosis mode, and FIG. 4B changes in response to the signal; It is a graph which shows an example of a pressure detection value.

5A is a graph showing a time change of a discharge amount command signal output from the controller to the regulator of the variable displacement hydraulic pump in the failure diagnosis mode, and FIG. 5B is set corresponding to the signal; It is a graph which shows the standard value and allowable range of pump discharge pressure.

FIG. 6 is a diagram showing a hydraulic circuit according to a second embodiment of the present invention.

FIG. 7 is a diagram showing a hydraulic circuit according to a third embodiment of the present invention.

FIG. 8 is a block diagram showing a functional configuration of a controller shown in FIG. 7;

9 is a graph showing a time change of a solenoid drive signal output from the controller of FIG. 8 to the electromagnetic switching valve in the failure diagnosis mode, and a standard value of a pump discharge pressure set corresponding to the signal.

FIG. 10 is a hydraulic circuit diagram showing a configuration example of a lock switching unit according to the present invention.

[Explanation of symbols]

10, 10A, 10B Variable displacement hydraulic pump 11 Regulator 14, 14A, 14B Hydraulic pilot switching valve (Control valve) 16 Flow control valve 20 Pump pressure sensor (Discharge pressure detecting means) 26 Mode switching switch 28 Electromagnetic switching valve 30 Controller 32 Control signal output means (control means) 34 Standard value memory 36 Failure determination means 58 Solenoid switching valve (lock switching means)

Claims (14)

[Claims] 1. An electronically controlled variable displacement hydraulic pump,
A control circuit for outputting a control signal for changing a discharge flow rate of the variable displacement hydraulic pump.A device for diagnosing a failure of the variable displacement hydraulic pump in a hydraulic circuit, the control device comprising: A normal control mode for performing the control operation, a failure diagnosis mode for outputting a control signal for giving a specific change to the discharge flow rate of the variable displacement hydraulic pump while the hydraulic equipment other than the variable displacement hydraulic pump is stopped, and Discharge pressure detecting means for detecting the discharge pressure of the variable displacement hydraulic pump, and the discharge pressure detecting means for outputting the control signal for actually giving the specific change in the failure diagnosis mode. Failure determination means for determining whether or not the variable displacement hydraulic pump is defective based on the pump discharge pressure detected by the pressure detection means. Self-diagnosis system of the hydraulic circuit to be. 2. The self-diagnosis device for a hydraulic circuit according to claim 1, wherein the pump discharge pressure detected when the control signal is output in the failure diagnosis mode is compared with a preset discharge pressure standard value. A self-diagnosis device for a hydraulic circuit, wherein the failure determination means is configured to determine whether or not the variable displacement hydraulic pump is defective. 3. The self-diagnosis device for a hydraulic circuit according to claim 1, wherein an unlocked state enabling operation of a control valve provided on a downstream side of the variable displacement hydraulic pump, and the operation being disabled. A self-diagnosis device for a hydraulic circuit, comprising: an operation lock means for switching to a lock state. 4. The self-diagnosis device for a hydraulic circuit according to claim 3, further comprising lock control means for switching the operation lock means to the lock state when the control means is switched to the failure diagnosis mode. Self-diagnosis device for hydraulic circuit. 5. A hydraulic pump, an electronically controlled control valve for controlling a flow state of hydraulic oil supplied from the hydraulic pump, and control means for outputting a control signal for operating the control valve. An apparatus for diagnosing a failure of the control valve of the hydraulic circuit, comprising: a control unit for performing a normal control operation in a normal control mode and a hydraulic pump with a constant discharge flow rate. A discharge pressure detecting means for detecting a discharge pressure of the hydraulic pump, which is configured to be switchable to a failure diagnosis mode for outputting a control signal for performing a specific failure diagnosis operation, It is determined whether or not the control valve has a failure based on the discharge pressure detected by the discharge pressure detecting means when the control valve outputs a control signal for causing the failure diagnosis operation to be performed. A self-diagnosis device for a hydraulic circuit, comprising: a failure determination unit. 6. A variable displacement hydraulic pump, an electronically controlled control valve for controlling a flow state of hydraulic oil supplied from the variable displacement hydraulic pump, and a control signal for controlling the control valve. A control circuit for outputting a control signal for changing a discharge flow rate of the variable displacement hydraulic pump; and a control valve of the hydraulic circuit and a device for diagnosing a failure of the variable displacement hydraulic pump, Means for outputting a control signal for causing the control valve to perform a specific failure diagnosing operation in a state where the discharge flow rate of the variable displacement hydraulic pump is constant, and a normal control mode in which a normal control operation is performed. A failure diagnosis module that sequentially performs an operation and an operation of outputting a control signal for giving a specific change to the discharge flow rate of the variable displacement hydraulic pump while the hydraulic equipment other than the variable displacement hydraulic pump is stopped. And a discharge pressure detecting means for detecting a discharge pressure of the variable displacement hydraulic pump, and for causing the control valve to actually perform the failure diagnosis operation in the failure diagnosis mode. When it is determined whether the control valve is malfunctioning based on the pump discharge pressure detected by the discharge pressure detecting means when the control signal is output, and when it is determined that the control valve is normal, The variable displacement based on the pump discharge pressure detected by the discharge pressure detecting means when a control signal for actually giving a specific change to the discharge flow rate of the variable displacement hydraulic pump in the failure diagnosis mode is output. A self-diagnosis device for a hydraulic circuit, comprising: failure determination means for determining whether or not the type hydraulic pump has failed. 7. The self-diagnosis device for a hydraulic circuit according to claim 5, wherein the control valve to be subjected to the failure diagnosis is an electronically controlled flow control valve having an adjustable opening area. Self-diagnosis device for hydraulic circuit. 8. The self-diagnosis device for a hydraulic circuit according to claim 7, wherein the control means is configured to output a control signal for continuously changing an opening area of the flow control valve as the failure diagnosis operation. And a failure determining means for determining whether or not the flow control valve is defective based on a comparison between a pump discharge pressure detected when the control signal is output and a preset discharge pressure standard value. A self-diagnosis device for a hydraulic circuit, comprising: 9. The self-diagnosis device for a hydraulic circuit according to claim 7, wherein the control means outputs a control signal for discontinuously switching an opening area of the flow control valve as the failure diagnosis operation. And the failure determining means is configured to determine that a failure has occurred when the change rate of the detected value of the discharge pressure of the hydraulic pump accompanying the output of the control signal from the control means is lower than a preset speed. A self-diagnosis device for a hydraulic circuit, comprising: 10. The self-diagnosis device for a hydraulic circuit according to claim 5, wherein the control valve to be subjected to the failure diagnosis includes:
A self-diagnosis device for a hydraulic circuit, which is an electromagnetic switching valve for switching a flow path of hydraulic oil discharged from the hydraulic pump. 11. The self-diagnosis device for a hydraulic circuit according to claim 10, wherein the control means is configured to output a control signal for causing the electromagnetic switching valve to perform a switching operation as the failure diagnosis operation. The failure determination means is configured to determine whether or not the electromagnetic switching valve is defective based on a comparison between a pump discharge pressure detected when the control signal is output from the control means and a preset standard value. A self-diagnosis device for a hydraulic circuit, characterized in that: 12. The self-diagnosis device for a hydraulic circuit according to claim 10, wherein the control means is configured to output a control signal for causing the electromagnetic switching valve to perform a switching operation as the failure diagnosis operation. The failure determination means is configured to determine that a failure has occurred when a change speed of the detection value of the discharge pressure of the hydraulic pump accompanying the output of the control signal of the control means is lower than a preset speed. Characteristic self-diagnosis device for hydraulic circuits. 13. The self-diagnosis device for a hydraulic circuit according to claim 5, wherein an unlocked state enabling operation of a control valve provided on a downstream side of the hydraulic pump and the operation being disabled. A self-diagnosis device for a hydraulic circuit, comprising: an operation lock means for switching to a locked state. 14. The self-diagnosis device for a hydraulic circuit according to claim 13, further comprising lock control means for switching the operation lock means to the locked state when the control means is switched to the failure diagnosis mode. Self-diagnosis device for hydraulic circuit.