JP2022091426A - Hydraulic system and its spool position calibration method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydraulic pressure system applicable to any type of centralized bleed-off type and individual bleed-off type.
A hydraulic system includes a center bypass passage 11, a parallel passage 12 arranged in parallel with the center bypass passage, and a plurality of hydraulic systems arranged in tandem in the center bypass passage and connected in parallel to the parallel passage. A directional control valve group having directional control valves 21, 22 and 23 and a bleed-off valve 14 arranged on the downstream side of the directional control valve group in the center bypass passage are provided, and each of the directional control valves has actuators 4, 5 and 5 thereof. , 6 respectively, which control the flow of hydraulic fluid from the parallel passage to the actuator according to the position of the spool, and the bleed-off valve is bleed-off from the center bypass passage by changing the opening area of the center bypass passage. Bleed-off Controls the flow rate.
[Selection diagram] Fig. 1

Description

The present invention relates to a hydraulic system that controls the flow of hydraulic fluid and a method for calibrating the spool position thereof.

Construction machinery is equipped with a hydraulic system to control the flow of hydraulic fluid to multiple actuators. As an example of the hydraulic pressure system, for example, the hydraulic pressure circuit of Patent Document 1 is known. In the hydraulic system of Patent Document 1, a plurality of directional control valves are arranged in tandem in the center bypass passage. Further, in the center bypass passage, a bleed-off valve is arranged further downstream of the plurality of directional control valves.

Japanese Unexamined Patent Publication No. 2014-001768

As the hydraulic pressure system provided in the construction machine, there is an individual bleed-off type hydraulic pressure system in addition to the centralized bleed-off type hydraulic pressure system such as the hydraulic pressure circuit of Patent Document 1. In the individual bleed-off type hydraulic system, each of the directional control valves arranged in tandem in the center bypass passage adjusts the opening degree of the center bypass passage. The centralized bleed-off type hydraulic system and the individual bleed-off type hydraulic system are formed by different passage configurations. Therefore, it is desired that the centralized bleed-off type hydraulic system and the individual bleed-off type hydraulic system are formed by a common passage configuration.

Therefore, an object of the present invention is to provide a hydraulic pressure system applicable to any type of centralized bleed-off type and individual bleed-off type, and a spool position calibration method thereof.

The hydraulic system of the present invention includes a center bypass passage to which a hydraulic fluid is supplied from a hydraulic pump, a parallel passage to which a hydraulic fluid is supplied from the hydraulic pump and arranged in parallel with the center bypass passage. A directional control valve group having a plurality of directional control valves arranged in tandem in the center bypass passage and connected in parallel to the parallel passage, and arranged on the downstream side of the directional control valve group in the center bypass passage. Each of the directional control valves is connected to an actuator and controls the flow of the hydraulic fluid from the parallel passage to the actuator according to the position of the spool, and the bleed-off valve is the bleed-off valve. By changing the opening area of the center bypass passage, the bleed-off flow rate bleeding off from the center bypass passage is controlled.

According to the present invention, the bleed-off valve is arranged on the downstream side of the center bypass passage. Therefore, a centralized bleed-off type passage configuration can be formed in a hydraulic system. Further, each of the directional control valves is connected in parallel to the parallel passage. Therefore, by configuring the directional control valve to throttle the center bypass passage according to the position of the spool, it is possible to form an individual bleed-off type passage configuration in the hydraulic system.

The spool position calibration method in the hydraulic system of the present invention is arranged in parallel with the center bypass passage to which the hydraulic fluid is supplied from the hydraulic pump and the hydraulic fluid to be supplied from the hydraulic pump and the center bypass passage. The parallel passage and the center bypass passage are arranged in tandem and connected in parallel to the parallel passage and connected to the actuator respectively, and the flow of the hydraulic fluid from the parallel passage to the actuator is flown from the parallel passage to the actuator according to the position of the spool. By changing the opening area of the directional control valve group having a plurality of directional control valves to be controlled and the center bypass passage arranged on the downstream side of the directional control valve group in the center bypass passage and according to the position of the valve body. It includes a bleed-off valve that controls the bleed-off flow rate bleed-off from the center bypass passage, a discharge pressure sensor that detects the discharge pressure of the hydraulic pump, and a control device that controls the movement of the spool and the valve body. A method in a hydraulic system, in which the unloading step of adjusting the movement of the valve body so that the opening area of the center bypass passage in the bleed-off valve is larger than the opening area of the center bypass passage in the directional control valve. The control device outputs a control signal to the direction control valve and moves the spool according to the control signal, and the discharge pressure sensor detects a change in the discharge pressure by moving the spool. Then, the position estimation step of estimating the position of the spool based on the detected discharge pressure is compared with the position of the spool estimated to be the control signal output to the direction control valve, and the control signal and the position of the spool are compared. It is a method including a calibration step for adjusting the relationship with.

According to the present invention, in a hydraulic system that can be applied to both the centralized bleed-off type and the individual bleed-off type, the deviation between the control signal and the spool position can be adjusted. As a result, for example, when a control signal is output according to the manipulated variable, it is possible to suppress the position of the spool with respect to the manipulated variable from fluctuating from system to system. That is, variations in operability are suppressed.

According to the present invention, it can be applied to any type of centralized bleed-off type and individual bleed-off type.

It is a circuit diagram which shows the hydraulic circuit at the time of performing centralized bleeding control in the hydraulic pressure system which concerns on 1st Embodiment of this invention. It is a circuit diagram which shows the hydraulic circuit at the time of performing individual bleeding control in the hydraulic pressure system of FIG. It is a circuit diagram which shows the flow of a pressure liquid at the time of operation in the hydraulic pressure system of FIG. It is a graph which shows the change of the opening area of the spool applied to each control valve in order to perform the calibration of the spool stroke in the hydraulic system of FIG. It is a flowchart which shows the procedure of the calibration performed in the hydraulic system of FIG. It is a circuit diagram which shows the hydraulic circuit of the hydraulic pressure system which concerns on 2nd Embodiment of this invention.

Hereinafter, the hydraulic pressure systems 1 and 1A according to the first and second embodiments according to the present invention will be described with reference to the above-mentioned drawings. It should be noted that the concept of the direction used in the following description is used for convenience in the explanation, and does not limit the direction of the configuration of the invention to that direction. Further, the hydraulic pressure systems 1, 1A described below are only one embodiment of the present invention. Therefore, the present invention is not limited to the embodiment, and can be added, deleted, or changed without departing from the spirit of the invention.

(First Embodiment)
<Hydraulic drive unit>
The hydraulic drive unit 2 shown in FIG. 1 is mounted on a hydraulic vehicle such as a construction vehicle and an industrial vehicle. The hydraulic drive unit 2 drives various devices (for example, excavator device, crane device, traveling device, etc.) provided in the hydraulic vehicle. More specifically, each device of the hydraulic vehicle includes actuators 4 to 6 such as the hydraulic motor 4, the first cylinder 5, and the second cylinder 6. Further, the hydraulic pressure drive unit 2 includes a hydraulic pressure pump 3 and a hydraulic pressure system 1. Then, the hydraulic pressure drive unit 2 supplies the hydraulic fluid discharged from the hydraulic pressure pump 3 to the hydraulic pressure motor 4, the first cylinder 5, and the second cylinder 6 via the hydraulic pressure system 1. As a result, the actuators 4 to 6 are operated to drive each device. In the following, each configuration of the hydraulic pressure system 1 will be described in more detail.

[Hydraulic pump]
The hydraulic pump 3 discharges the hydraulic fluid. More specifically, the hydraulic pump 3 is connected to a drive source (eg, engine or motor) (not shown). Then, the hydraulic pump 3 is driven by the drive source to discharge the hydraulic fluid. Further, the hydraulic pressure pump 3 is a variable capacity pump, and is a variable capacity swash plate pump in the present embodiment. That is, the hydraulic pump 3 is provided with a regulator 8. Then, the regulator 8 changes the discharge flow rate of the hydraulic pump 3 according to the input pump signal. As a result, the hydraulic pressure pump 3 discharges the hydraulic fluid having a discharge flow rate according to the pump signal. The hydraulic pressure pump 3 may be a fixed-capacity pump or a variable-capacity axle pump.

[Hydraulic system]
The hydraulic pressure system 1 is connected to the hydraulic pressure pump 3. Then, the hydraulic pressure system 1 controls the flow of the hydraulic fluid from the hydraulic pressure pump 3 to the actuators 4 to 6 to drive various devices. More specifically, the hydraulic pressure system 1 includes a center bypass passage 11, a parallel passage 12, a directional control valve group 13, a bleed-off valve 14, a discharge pressure sensor 15, and a load pressure sensor 16a to 16c. It includes an operating device 17 and a control device 18.

[Center Bypass Passage]
The center bypass passage 11 is connected to the hydraulic pump 3. Then, the hydraulic fluid from the hydraulic pump 3 is supplied to the center bypass passage 11. Further, a tank 7 is connected to the most downstream side of the center bypass passage 11.

[Parallel passage]
The parallel passage 12 is arranged in parallel with the center bypass passage 11. Then, the hydraulic fluid is supplied to the parallel passage 12 from the hydraulic pump 3. More specifically, the parallel passage 12 branches at the branch point 11a of the center bypass passage 11 and is arranged in parallel with the center bypass passage 11.

[Direction control valve group]
The directional control valve group 13 has a plurality of directional control valves 21 to 23. The plurality of directional control valves 21 to 23 are arranged in tandem in the center bypass passage 11 and connected in parallel to the parallel passage 12. More specifically, the plurality of directional control valves 21 to 23 are provided corresponding to the actuators 4 to 6, respectively. In the present embodiment, the directional control valve group 13 includes the same number of directional control valves 21 to 23 as the number of actuators, that is, three directional control valves 21 to 23. The number of directional control valves included in the directional control valve group 13 is not limited to three, and may be two or four or more. Further, the number of directional control valves does not necessarily have to be the same as the number of actuators.

Each of the directional control valves 21-23 is connected to the corresponding actuators 4-6, respectively, and controls the flow of hydraulic fluid to the corresponding actuators 4-6. In the present embodiment, the first direction control valve 21 controls the flow of the hydraulic fluid to the hydraulic motor 4, and the second direction control valve 22 controls the flow of the hydraulic fluid to the first cylinder 5, and the third direction. The control valve 23 controls the flow of the hydraulic fluid with respect to the second cylinder 6. More specifically, each of the directional control valves 21 to 23 has spools 21a to 23a. Each of the direction control valves 21 to 23 controls the flow of the hydraulic fluid (that is, the flow direction and the flow rate of the hydraulic oil) from the parallel passage 12 to the corresponding actuators 4 to 6 according to the positions of the spools 21a to 23a. do. Further, each of the directional control valves 21 to 23 always opens the center bypass passage 11 regardless of the positions of the spools 21a to 23a when performing the centralized bleed-off control described later. On the other hand, when performing individual bleed-off control described later, as shown in FIG. 2, each of the directional control valves 21 to 23 changes the opening area of the center bypass passage 11 according to the positions of the spools 21b to 23b.

Further, the directional control valves 21 to 23 are center-open type electromagnetic pilot type spool valves in the present embodiment. That is, the directional control valves 21 to 23 output the pilot pressure corresponding to the input control signal to the spools 21a to 23a (or 21b to 23b), and the spools 21a to the positions corresponding to the input control signal. Move 23a (or 21b-23b). As a result, each of the directional control valves 21 to 23 controls the flow of the hydraulic fluid (that is, the flow direction and the flow rate of the hydraulic oil) to the actuators 4 to 6 according to the input control signal. The direction control valves 21 to 23 are not limited to the electromagnetic pilot type spool valve, and may be an electric drive type spool valve or a pilot type spool valve driven by an electric motor or the like.

[Bleed-off valve]
The bleed-off valve 14 is arranged on the downstream side of the directional control valve group 13 in the center bypass passage 11. Further, the bleed-off valve 14 controls the bleed-off flow rate of bleed-off from the center bypass passage 11 to the tank 7 by changing the opening area of the center bypass passage 11. More specifically, the bleed-off valve 14 has a valve body 14a (spool in this embodiment). Then, the bleed-off valve 14 changes the position of the valve body 14a according to the input bleed-off signal. Further, the bleed-off valve 14 changes the opening area of the center bypass passage 11 according to the position of the valve body 14a. As a result, the bleed-off valve 14 controls the bleed-off flow rate. In the present embodiment, the bleed-off valve 14 is an inverse proportional type solenoid valve. The bleed-off valve 14 may be a direct proportional solenoid valve.

[Discharge pressure sensor]
The discharge pressure sensor 15 detects the discharge pressure of the hydraulic pump 3. More specifically, the discharge pressure sensor 15 is connected to the discharge port 3a of the hydraulic pump 3. In the present embodiment, the discharge pressure sensor 15 is connected to the discharge port 3a via the center bypass passage 11. The discharge pressure sensor 15 outputs a signal corresponding to the detected discharge pressure.

[Load pressure sensor]
The load pressure sensors 16a to 16c detect the load pressure of the hydraulic fluid supplied to the corresponding actuators 4 to 6. More specifically, the load pressure sensors 16a to 16c are connected to the passages connecting the ports of the corresponding actuators 4 to 6 and the directional control valves 21 to 23, respectively. Then, the load pressure sensors 16a to 16c detect the load pressure which is the hydraulic pressure of the hydraulic fluid flowing through the actuators 4 to 6. Further, the load pressure sensors 16a to 16c output a signal corresponding to the detected load pressure.

[Operating device]
The operation device 17 outputs an operation command for operating the actuators 4 to 6. More specifically, the operating device 17 has a number of operating levers 17a to 17c corresponding to the actuators 4 to 6. In the present embodiment, the operating device 17 has one operating lever 17a to 17c for each of the actuators 4 to 6. The first operating lever 17a corresponds to the hydraulic motor 4, the second operating lever 17b corresponds to the first cylinder 5, and the third operating lever 1c corresponds to the second cylinder 6. The number of operating levers is not limited to the number described above, and the operating levers provided for the actuators 5 and 6 may be one operating lever that can be operated in all directions. The operation device 17 outputs an operation command according to the operation direction and the operation amount of the operation levers 17a to 17c.

[Control device]
The control device 18 controls the movements of the spools 21a to 23a (or 21b to 23b) of the directional control valves 21 to 23 and the valve body 14a of the bleed-off valve 14. Further, the control device 18 controls the discharge flow rate of the hydraulic pump 3. Further, the control device 18 calibrates the spools 21a to 23a (or 21b to 23b) based on the signal from the discharge pressure sensor 15. More specifically, the control device 18 outputs a control signal to each of the direction control valves 21 to 23 in response to an operation command from the operation device 17. As a result, the positions of the spools 21a to 23a (or 21b to 23b) of the directional control valves 21 to 23 are controlled. Further, the control device 18 outputs a bleed-off signal to the bleed-off valve 14 in response to an operation command from the operation device 17. As a result, the valve body 14a moves. Further, the control device 18 outputs a pump signal corresponding to the operation command from the operation device 17 to the regulator 8. As a result, the control device 18 can discharge the hydraulic fluid having a discharge flow rate according to the operation amount to the hydraulic pump 3.

<Drive operation of hydraulic system>
In the hydraulic pressure drive unit 2, when the operation levers 17a to 17c of the operation device 17 are operated, a pump signal corresponding to the operation amount of the operation levers 17a to 17c is output from the control device 18 to the regulator 8. As a result, the hydraulic pump 3 discharges the hydraulic fluid according to the discharge flow rate according to the operation amount. That is, in the hydraulic pressure drive unit 2, positive control is performed with respect to the discharge flow rate of the hydraulic pressure pump 3. Further, in the hydraulic pressure system 1, when the operating levers 17a to 17c of the operating device 17 are operated, the hydraulic system 1 operates as follows.

[Centralized bleed-off control]
In the hydraulic system 1, when the centralized bleed-off control is executed, the spools 21a to 23a as shown in FIG. 1 are applied to the directional control valves 21 to 23. Here, the spools 21a to 23a open the center bypass passage 11 regardless of the position as described above. Then, when at least one of the operation levers 17a to 17c of the operation device 17, for example, the second operation lever 17b is operated, the control device 18 operates as follows.

When the second operation lever 17b is operated, the control device 18 moves the spool 22a of the second direction control valve 22 according to the operation direction and the operation amount (see FIG. 3). Further, the control device 18 controls the discharge flow rate of the hydraulic pump 3 by operating the regulator 8 according to the operation amount of the second operating lever 17b. Further, the control device 18 controls the opening area of the center bypass passage 11 by moving the valve body 14a of the bleed-off valve 14 according to the operation amount of the second operating lever 17b. As a result, the bleed-off flow rate in the hydraulic pressure system 1 is controlled (see the thick line in FIG. 3), and the hydraulic fluid having a flow rate corresponding to the operation amount is supplied to the first cylinder 5 (see the thick line in FIG. 3).

On the other hand, the same applies when the operating levers 17a and 17c are operated in the hydraulic pressure system 1 and when at least two or more of the operating levers 17a to 17c are operated at the same time. That is, the operating device 17 controls the positions of the spools 21a to 23a according to the operating direction and operating amount of the operated operating levers 17a to 17c. Further, the control device 18 controls the discharge flow rate of the hydraulic pump 3 and moves the valve body 14a according to the operation amount of the operation levers 17a to 17c. As a result, the bleed-off flow rate in the hydraulic pressure system 1 is controlled, and the hydraulic fluid having a flow rate corresponding to the operation amount is supplied to the actuators 4 to 6. As described above, in the hydraulic pressure system 1, centralized bleed-off control can be realized by applying the spools 21a to 23a.

[Individual bleed-off control]
In the hydraulic system 1, when the individual bleed-off control is executed, the spools 21b to 23b as shown in FIG. 2 are applied to the directional control valves 21 to 23. Here, the spools 21b to 23b change the opening area of the center bypass passage 11 according to the positions of the spools 21b to 23b as described above. More specifically, the spools 21b to 23b reduce the opening area of the center bypass passage 11 according to the amount of movement from the neutral position. Then, when at least one of the operation levers 17a to 17c of the operation device 17, for example, the second operation lever 17b is operated, the control device 18 operates as follows.

The control device 18 increases the opening area of the center bypass passage 11 in the bleed-off valve 14 regardless of the amount of operation of the second operating lever 17b. In the present embodiment, the control device 18 fully opens the opening area of the center bypass passage 11 in the bleed-off valve 14. Then, for example, when the second operating lever 17b is operated, the control device 18 controls the discharge flow rate of the hydraulic pump 3 by operating the regulator 8 according to the operation amount. Further, the control device 18 moves the spool 22b of the second direction control valve 22 according to the operation direction and the operation amount of the second operation lever 17b. As a result, the opening area of the center bypass passage 11 changes according to the position of the spool 21b, that is, changes according to the operation amount of the second operating lever 17b. As a result, the bleed-off flow rate is controlled by the spool 21b in the hydraulic pressure system 1 (see the thick line in FIG. 2), and the hydraulic fluid having a flow rate corresponding to the operation amount is supplied to the first cylinder 5 (see the thick line in FIG. 2). ).

The same applies when the operating levers 17a and 17c are operated in the hydraulic pressure system 1 and when at least two or more of the operating levers 17a to 17c are operated at the same time. That is, the operating device 17 fully opens the center bypass passage 11 in the bleed-off valve 14 and controls the discharge flow rate of the hydraulic pump 3 according to the operating amount of the operating levers 17a to 17c. Then, the control device 18 controls the positions of the spools 21b to 23b according to the operation direction and the operation amount of the operated operation levers 17a to 17c. As a result, the bleed-off flow rate in the hydraulic pressure system 1 is controlled, and the hydraulic fluid having a flow rate corresponding to the operation amount is supplied to the actuators 4 to 6. As described above, in the hydraulic pressure system 1, individual bleed-off control can be realized by applying the spools 21b to 23b.

In the hydraulic system 1 of the present embodiment, the bleed-off valve 14 is arranged on the downstream side of the center bypass passage 11. Therefore, a centralized bleed-off type passage configuration can be formed in the hydraulic pressure system 1. As a result, centralized bleed-off control is realized by applying the spools 21a to 23a. Further, each of the directional control valves 21 to 23 is connected to the parallel passage 12 in parallel. Therefore, by configuring the directional control valves 21 to 23 so as to throttle the center bypass passage 11 according to the positions of the spools 21b to 23b, it is possible to form an individual bleed-off type passage configuration in the hydraulic system 1. .. As a result, individual bleed-off control is realized by applying the spools 21b to 23b.

<Calibration operation of hydraulic system>
In the hydraulic system 1, the control device 18 outputs a control signal (current or voltage) to the directional control valves 21 to 23 in order to move the spools 21a to 23a (or 21b to 23b) to a predetermined position. However, the directional control valves 21 to 23 may shift the spools 21a to 23a (or 21b to 23b) from a predetermined position with respect to the control signal. Therefore, the hydraulic pressure system 1 can calibrate the direction control valves 21 to 23 by using the following spools 21a to 23a (or 21b to 23b). That is, the spools 21a to 23a (or 21b to 23b) have the opening characteristics as shown in FIG. The slope of the opening area of the spools 21a to 23a (or 21b to 23b) changes before and after the predetermined stroke amount s1 (inflection point) (see the one-dot chain line L1 in FIG. 4). Then, in the hydraulic pressure system 1, the control device 18 executes the calibration process as shown in FIG. 5 in order to calibrate the spools 21a to 23a (or 21b to 23b). In the following, the calibration process of the spool 21a of the first direction control valve 21 will be described. For the description of the calibration process of the spools 22a and 23a of the other directional control valves 22 and 23 performed by the same method, the description of the calibration process of the spool 21a will be referred to, and the details will be omitted. When the calibration process is executed, the process proceeds to step S1.

In step S1 which is an unloading step, the opening area of the center bypass passage 11 in the bleed-off valve 14 (see the solid line L2 in FIG. 4) is larger than the opening area of the center bypass passage 11 in the directional control valves 21 to 23. Adjust the movement of the body 14a. In the present embodiment, the control device 18 puts the hydraulic pressure system 1 in the unload state. More specifically, the control device 18 outputs a bleed-off signal to the bleed-off valve 14 to increase the opening area of the center bypass passage 11 in the bleed-off valve 14. In the present embodiment, the control device 18 fully opens the opening area of the center bypass passage 11 in the bleed-off valve 14. Then, the process proceeds to step S2.

In step S2, which is the spool movement step, the control device 18 outputs a control signal to the first-direction control valve 21. As a result, the first direction control valve 21 moves the spool 21a according to the input control signal. When the spool 21a is moved, the opening area of the center bypass passage 11 in the first direction control valve 21 is changed. When the position of the spool 21a is changed, the process proceeds to step S3.

In the position estimation step, the discharge pressure sensor 15 detects a change in the discharge pressure. Then, the control device 18 estimates the position of the spool 21a based on the detected discharge pressure. More specifically, when the spool 21a is moved in step S2, the control device 18 describes the discharge pressure at each position and the load pressure of the hydraulic pressure motor 4 based on the signals from the discharge pressure sensor 15 and the load pressure sensor 16a. To get. Then, the control device 18 stores the acquired discharge pressure and load pressure in association with the position of the spool 21a, that is, the stroke amount. Further, the control device 18 calculates the opening area for each stroke amount based on the discharge pressure and the load pressure stored in association with each other, and acquires the opening characteristic based on the calculated opening area. Then, the control device 18 estimates the position of the spool 21a with respect to the control signal output based on the acquired inflection point of the aperture characteristic. When the position of the spool 21a is estimated, the process proceeds to step S4.

In step S4, which is a calibration step, the control signal output to the directional control valve 21 and the estimated position of the spool 21a are compared, and the relationship between the control signal and the position of the spool 21a is adjusted. More specifically, the control device 18 adjusts the relationship between the control signal and the position of the spool 21a when there is a deviation between the position to be moved by the control signal and the position of the spool 21a estimated to be moved. Therefore, the control device 18 compares the control signal with the estimated position (stroke amount) of the spool 21a. Then, the control device 18 acquires a control signal when the spool 21a reaches the position of the inflection point. Then, the control device 18 adjusts the relationship between the control signal and the position of the spool 21a so as to be a value for moving the acquired control signal to the position of the inflection point. When the relationship between the control signal and the spool position is adjusted in this way, the calibration is completed.

In the hydraulic system 1 of the present embodiment, by using the spools 21a to 23a applied in the centralized bleed-off control as described above, the centralized bleed-off control and the positions of the spools 21a to 23a in the centralized bleed-off type passage configuration are used. Both calibrations can be achieved. That is, during the centralized bleed-off control, the opening area of the bleed-off valve 14 (see the solid line L2 in FIG. 4) in the center bypass passage 11 is always larger than the opening area of the directional control valves 21 to 23 as shown in FIG. Therefore, both the hydraulic pressure system 1 centralized bleed-off control and the calibration of the positions of the spools 21a to 23a can be realized. Further, in the hydraulic pressure system 1, by using the spools 21b to 23b applied in the individual bleed-off control, it is possible to realize the calibration of the positions of the spools 21b to 23 in the individual bleed-off type passage configuration. As described above, in the hydraulic pressure system 1, the spool position can be calibrated in both the centralized bleed-off type passage configuration and the individual bleed-off type passage configuration.

Further, in the hydraulic pressure system 1, the deviation between the control signal and the positions of the spools 21a to 23a (or 21b to 23b) can be adjusted. As a result, when the control signal corresponding to the operation amount is output, it is possible to suppress the positions of the spools 21a to 23a (or 21b to 23b) from being scattered for each system with respect to the operation amount. Therefore, it is possible to suppress the operation of the actuators 4 to 6 from varying with respect to the operation amount for each system, that is, the variation in operability is suppressed.

(Second Embodiment)
The hydraulic pressure system 1A of the second embodiment is similar in configuration to the hydraulic pressure system 1 of the first embodiment. Therefore, the configuration of the hydraulic pressure system 1A of the second embodiment will be mainly described as being different from the hydraulic pressure system 1 of the first embodiment, and the same configuration will be designated by the same reference numerals and description thereof will be omitted. ..

The hydraulic pressure system 1A of the second embodiment is mounted on the hydraulic pressure drive unit 2A. Then, the hydraulic pressure drive unit 2A uses the hydraulic pressure system 1A to perform negative control on the discharge flow rate of the hydraulic pressure pump 3. More specifically, the hydraulic pressure system 1A includes a directional control valve group 13, a bleed-off valve 14, a discharge pressure sensor 15, load pressure sensors 16a to 16c, an operating device 17, and a control device 18. Further, it has a throttle 31, a relief valve 32, and a negative control passage 33.

The throttle 31 is arranged on the downstream side of the bleed-off valve 14 in the center bypass passage 11. As a result, in the center bypass passage 11, a hydraulic pressure corresponding to the flow rate of the operating pressure flowing through the center bypass passage 11 can be generated on the upstream side of the throttle 31.

The relief valve 32 is arranged on the downstream side of the bleed-off valve 14 in the center bypass passage 11, and is further arranged so as to be parallel to the throttle 31. As a result, when the pressure of the hydraulic fluid flowing on the upstream side of the throttle 31 of the center bypass passage 11 exceeds a predetermined relief pressure, the hydraulic fluid flowing on the upstream side of the throttle 31 is discharged to the tank 7.

The negative control passage 33 is connected between the throttle 31 and the bleed-off valve 14. Further, the negative control passage 33 is connected to the regulator 8. Then, the negative control passage 33 supplies the hydraulic pressure on the upstream side of the throttle 31, that is, the negative control pressure (hereinafter, referred to as “negative control pressure”) to the regulator 8.

In the hydraulic pressure system 1 configured in this way, the negative control pressure corresponding to the bleed-off flow rate is input to the regulator 8 as a pump signal. As a result, the discharge flow rate of the hydraulic pump 3 is controlled according to the negative pressure. That is, negative control is performed on the discharge flow rate of the hydraulic pressure pump 3, and a negative control circuit can be realized in the hydraulic pressure system 1.

In addition, the hydraulic system 1A of the second embodiment has the same effect as that of the hydraulic system 1 of the first embodiment.

(Other embodiments)
In the hydraulic pressure systems 1 and 1A of the first and second embodiments, the centralized bleed-off control is carried out by applying the spools 21a to 23a having the opening characteristics as shown in FIG. 4, but such a centralized bleed-off control is not always performed. It is not necessary to apply the spools 21a to 23a. For example, the spools 21a to 23a may have the center bypass passage 11 fully opened at all times, or may have no inflection in the opening characteristics. That is, the spools 21a to 23a may have a larger opening area of each of the directional control valves 21 to 23 than the opening area of the valve body 14a in the center bypass passage 11 during the centralized bleed-off control.

1,1A Hydraulic system 3 Hydraulic pump 4-6 Actuator 11 Center bypass passage 12 Parallel passage 13 Directional control valve group 14 Bleed-off valve 14a Valve body 15 Discharge pressure sensor 18 Control device 21 Directional control valve 21a, 21b Spool 22 directions Control valve 22a, 22b Spool 23 Directional control valve 23a, 23b Spool 31 Squeezing 32 Relief valve 33 Negative control passage

Claims (6)

The center bypass passage where the hydraulic fluid is supplied from the hydraulic pump,
A parallel passage to which the hydraulic fluid is supplied from the hydraulic pump and arranged in parallel with the center bypass passage,
A group of directional control valves having a plurality of directional control valves arranged in tandem in the center bypass passage and connected in parallel to the parallel passage.
The center bypass passage is provided with a bleed-off valve arranged on the downstream side of the directional control valve group.
Each of the directional control valves is connected to the actuator and controls the flow of the hydraulic fluid from the parallel passage to the actuator according to the position of the spool.
The bleed-off valve is a hydraulic system that controls the bleed-off flow rate bleeding off from the center bypass passage by changing the opening area of the center bypass passage. The directional control valve changes the opening area of the center bypass passage according to the position of the spool.
The bleed-off valve changes the opening area of the center bypass passage according to the position of the valve body.
The hydraulic system according to claim 1, wherein the spool has a larger opening area for each position than the valve body of the bleed-off valve. A discharge pressure sensor that detects the discharge pressure of the hydraulic pump and
Further provided with a control device for controlling the movement of the spool and the valve body,
The control device adjusts the movement of the valve body and moves the spool so that the opening area of the center bypass passage in the bleed-off valve is larger than the opening area of the center bypass passage in the directional control valve. The hydraulic pressure system according to claim 2, wherein the change in the discharge pressure is detected by the discharge pressure sensor, and the position of the spool is estimated based on the detected discharge pressure. The directional control valve changes the position of the spool according to the input control signal.
The hydraulic system according to claim 3, wherein the control device compares a control signal output to the directional control valve with an estimated position of the spool, and adjusts the relationship between the control signal and the position of the spool. .. In the center bypass passage, the throttle arranged on the downstream side of the bleed-off valve,
In the center bypass passage, a relief valve arranged on the downstream side of the bleed-off valve so as to be parallel to the throttle,
The hydraulic system according to any one of claims 1 to 4, further comprising a negative control passage connected between the throttle and the bleed-off valve in the center bypass passage. A center bypass passage to which the hydraulic fluid is supplied from the hydraulic pump, a parallel passage to which the hydraulic fluid is supplied from the hydraulic pump and arranged in parallel with the center bypass passage, and a parallel passage arranged in tandem in the center bypass passage. A group of directional control valves having a plurality of directional control valves connected in parallel to the parallel passage and connected to the actuator, respectively, to control the flow of the hydraulic fluid from the parallel passage to the actuator according to the position of the spool. , The bleed-off flow rate bleeding off from the center bypass passage is controlled by changing the opening area of the center bypass passage, which is arranged on the downstream side of the direction control valve group in the center bypass passage and according to the position of the valve body. A spool position calibration method in a hydraulic system including a bleed-off valve, a discharge pressure sensor for detecting the discharge pressure of the hydraulic pump, and a control device for controlling the movement of the spool and the valve body.
An unloading step of adjusting the movement of the valve body so that the opening area of the center bypass passage in the bleed-off valve is larger than the opening area of the center bypass passage in the directional control valve.
A spool moving step in which a control signal is output from the control device to the directional control valve and the spool is moved according to the control signal.
A position estimation step in which a change in discharge pressure is detected by the discharge pressure sensor by moving the spool and the position of the spool is estimated based on the detected discharge pressure.
Spool position calibration in a hydraulic system comprising a calibration step of comparing the control signal output to the directional control valve with the estimated position of the spool and adjusting the relationship between the control signal and the position of the spool. Method.

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