JP5938356B2 - Hydraulic drive device for hydraulic excavator - Google Patents

Description

  The present invention relates to a hydraulic drive device for a hydraulic excavator provided with a switching valve for communicating a rod chamber of a boom cylinder and a bottom chamber of an arm cylinder.

  There exists a thing shown by patent document 1 as this kind of prior art. This prior art is a hydraulic drive device for a hydraulic excavator, and includes a main hydraulic pump and a boom cylinder and an arm cylinder that are driven by pressure oil discharged from the main hydraulic pump and have a rod chamber and a bottom chamber, respectively. ing. This prior art also provides a directional control valve for a boom that controls the flow of pressure oil supplied from the main hydraulic pump to the boom cylinder, and an arm for controlling the flow of pressure oil supplied from the main hydraulic pump to the arm cylinder. A direction control valve, a boom operation device that switches the boom direction control valve, and an arm operation device that switches the arm direction control valve are provided. Furthermore, this prior art includes a switching valve that communicates the rod chamber of the boom cylinder and the bottom chamber of the arm cylinder when the pressure in the rod chamber of the boom cylinder exceeds a predetermined pressure.

  In the related art configured as described above, when the pressure in the rod chamber of the boom cylinder becomes higher than a predetermined pressure due to the excavation reaction force during the arm cloud single operation, the pressure oil in the rod chamber of the boom cylinder is passed through the switching valve. Can be sent to the bottom chamber of the arm cylinder. Therefore, the boom cylinder is extended, the excavation reaction force in the arm cloud operation can be released, and the airframe can be prevented from being lifted. Further, since the pressure oil flowing out from the rod chamber of the boom cylinder is supplied to the bottom chamber of the arm cylinder, it is possible to increase the speed in the extending direction of the arm cylinder and to increase the operation speed of the arm cloud.

International Publication No. WO2004 / 005727 Pamphlet

  In the above-described prior art, the switching valve is maintained at the maximum opening area when excavation work is being performed by the combined operation of raising the boom and the arm cloud, that is, when the combined operation of the boom cylinder and the arm cylinder is being performed. If the pressure difference between the boom cylinder rod chamber and the arm cylinder bottom chamber is large, the hydraulic oil in the boom cylinder rod chamber will generate a shock when passing through the switching valve with a large opening area. To do. This shock reduces operability. In addition, when performing highly accurate work, the work accuracy is likely to deteriorate due to shock.

  The present invention has been made based on the actual situation in the above-described prior art, and its purpose is generated in the airframe in response to the differential pressure between the boom cylinder rod pressure and the arm cylinder bottom pressure during boom raising and arm cloud combined operation. It is an object of the present invention to provide a hydraulic drive device for a hydraulic excavator that can suppress a shock.

  In order to achieve this object, the present invention provides a main hydraulic pump, a boom cylinder and an arm cylinder that are driven by pressure oil discharged from the main hydraulic pump and each have a rod chamber and a bottom chamber, and the main hydraulic pump. A boom direction control valve that controls the flow of pressure oil supplied from the main hydraulic pump to the arm cylinder, and the boom direction control valve that controls the flow of pressure oil supplied from the main hydraulic pump to the arm cylinder; A boom operating device for switching the directional control valve, an arm operating device for switching the arm directional control valve, and when the pressure in the rod chamber of the boom cylinder is higher than a predetermined pressure. The hydraulic pressure of a hydraulic excavator comprising a switching valve for communicating the rod chamber of the boom cylinder and the bottom chamber of the arm cylinder In the moving device, a first pressure detection unit for detecting the rod pressure of the boom cylinder, a second pressure detection unit for detecting the bottom pressure of the arm cylinder, and the boom cylinder detected by the first pressure detection unit. When the differential pressure between the rod pressure and the bottom pressure of the arm cylinder detected by the second pressure detector is equal to or higher than a predetermined pressure, the rod chamber of the boom cylinder and the bottom chamber of the arm cylinder are communicated with each other. And an opening control unit that controls the switching valve so as to reduce an opening area of the switching valve.

  In the present invention configured as described above, when the first pressure detection unit and the second pressure detection unit detect that the differential pressure between the rod pressure of the boom cylinder and the bottom pressure of the arm cylinder is equal to or higher than a predetermined pressure, The switching valve is controlled by the opening control unit so that the opening area is reduced. That is, the flow rate of the pressure oil that is sent from the rod chamber of the boom cylinder to the bottom chamber of the arm cylinder is less than that when the switching valve is maintained at the maximum opening area. As a result, when the boom is raised and the arm cloud is combined, it is possible to suppress a shock generated in the airframe according to the differential pressure between the rod pressure of the boom cylinder and the bottom pressure of the arm cylinder.

  Further, the present invention provides a first operation amount detection unit that detects an operation amount of the boom operation device when the boom is raised, and a second operation that detects an operation amount of the arm operation device when the arm is clouded. An operation amount detection unit, wherein the opening control unit is configured so that the boom operation device and the arm operation device are in response to signals output from the first operation amount detection unit and the second operation amount detection unit. A discriminating unit for discriminating whether or not the boom is raised and the arm cloud is operated, and the rod pressure of the boom cylinder detected by the first pressure detector and the arm cylinder detected by the second pressure detector An operation area for obtaining a differential pressure from the bottom pressure of the valve, and an opening area such that the opening area of the switching valve is smaller than the maximum when the pressure difference obtained by the operation section is equal to or greater than the predetermined pressure. A first function generator configured to output, and the opening controller is configured such that the boom operating device and the arm operating device are respectively raised in the boom and operated by the arm cloud in the determining unit. When it is determined, the switching valve is controlled according to the opening area output from the first function generator.

  In the present invention configured as described above, the opening control unit controls the opening area of the switching valve only when the boom raising / arm cloud combined operation is performed by the first operation amount detecting unit and the second operation amount detecting unit. Control to make it small can be implemented.

  Further, the present invention is the above invention, wherein the opening control unit includes: a second function generating unit in which a relationship between the operation amount of the first operation amount detection unit and the opening area is set; and the second operation amount detection unit. A minimum value of the opening area respectively output from the third function generating unit in which the relationship between the operation amount and the opening area is set, and the first function generating unit, the second function generating unit, and the third function generating unit. A minimum value selection unit to be selected, and the opening control unit detects the minimum when the determination unit determines that the boom operation device and the arm operation device are operated to raise the boom and operate the arm cloud, respectively. The switching valve is controlled to have an opening area output from the value selection unit.

  In the present invention configured as described above, each of the setting in the second function generating unit related to the boom raising operation and the setting in the third function generating unit related to the arm cloud operation are performed by the hydraulic excavator. -By considering the excavation work by the arm cloud combined operation, it is possible to obtain high work accuracy of the excavation work and to suppress the shock of the airframe during the excavation work.

  According to the present invention, in the above invention, the first pressure detection unit includes a first pressure sensor, the second pressure detection unit includes a second pressure sensor, and the first operation amount detection unit includes a third pressure sensor. The second manipulated variable detector comprises a fourth pressure sensor, the control port of the switching valve comprising a solenoid valve capable of supplying a pilot pressure for controlling the opening area of the switching valve, and the opening control unit Comprises a controller that outputs a control signal for controlling the solenoid valve, and the controller includes the determination unit, the calculation unit, the first function generation unit, the second function generation unit, and the third function generation unit. A function generation unit and the minimum value selection unit, and when it is determined by the determination unit that the boom operation device and the arm operation device are respectively operated to raise the boom and operate the arm cloud, A permission unit that permits execution of control of the opening area of the valve, and a control signal that corresponds to the opening area that is output from the minimum value selection unit when control of the opening area of the switching valve is permitted by the permission unit. And an output unit that outputs the signal to the electromagnetic valve.

  The present invention provides a first pressure detection unit, a second pressure detection unit, and an opening control unit when a differential pressure between the rod pressure of the boom cylinder and the bottom pressure of the arm cylinder is large during boom raising / arm cloud combined operation. By controlling the switching valve so as to reduce the opening area, it is possible to suppress the shock of the airframe that occurs when the pressure oil sent from the rod chamber of the boom cylinder to the bottom chamber of the arm cylinder passes through the switching valve. . Thereby, operativity can be improved compared with the past, and high work accuracy can be secured.

1 is a side view showing a hydraulic excavator provided with an embodiment of a hydraulic drive device according to the present invention. It is a hydraulic circuit diagram which shows the structure of the hydraulic drive device which concerns on this embodiment. It is a block diagram which shows the principal part structure of the controller with which this embodiment is equipped. It is a block diagram which shows the principal part structure of the controller with which another embodiment of this invention is equipped.

  Embodiments of a hydraulic drive device for a hydraulic excavator according to the present invention will be described below with reference to the drawings.

  As shown in FIG. 1, a hydraulic excavator provided with the hydraulic drive device according to the present embodiment includes a traveling body 1, a revolving body 2 provided on the traveling body 1, and the revolving body 2 rotating in the vertical direction. A boom 3 that can be mounted, an arm 4 that is mounted on the boom 3 so as to be pivotable in the vertical direction, and a bucket 5 that is mounted on the arm 4 so as to be pivotable in the vertical direction are provided. The boom 3, the arm 4, and the bucket 5 constitute a front work machine. A boom cylinder 6 that drives the boom 3, an arm cylinder 7 that drives the arm 4, and a bucket cylinder 8 that drives the bucket 5 are provided.

  In the hydraulic excavator configured as described above, the boom cylinder 6 extends as shown by an arrow 13 in FIG. Raising is done. Further, along with the boom raising operation, the arm cylinder 7 extends as shown by an arrow 9 and the arm 4 rotates as shown by an arrow 11 to perform an arm cloud operation. Further, along with such boom raising / arm cloud combined operation, the bucket cylinder 8 is extended in the direction of the arrow 10 and the bucket 5 is rotated as indicated by the arrow 11. A desired excavation work or the like is performed by these operations.

  As shown in FIG. 2, the boom cylinder 6 includes a bottom chamber 6a and a rod chamber 6b. When pressure oil is supplied to the bottom chamber 6a, the boom cylinder 6 is extended to raise the boom, and the rod chamber By supplying pressure oil to 6b, the boom cylinder 6 contracts and the boom is lowered. The arm cylinder 7 also includes a bottom chamber 7a and a rod chamber 7b. When pressure oil is supplied to the bottom chamber 7a, arm cloud is performed, and when pressure oil is supplied to the rod chamber 7b, arm dump is performed. The

  As shown in FIG. 2, the hydraulic drive apparatus according to this embodiment including the boom cylinder 6 and the arm cylinder 7 includes an engine 20, a main hydraulic pump 21 driven by the engine 20, and a pilot pump 22. And. In the present embodiment, a boom direction control valve 23 for controlling the flow of pressure oil supplied from the main hydraulic pump 21 to the boom cylinder 6 and the flow of pressure oil supplied from the main hydraulic pump 21 to the arm cylinder 7 are used. An arm direction control valve 24 for controlling the boom direction, a boom operation device 25 for switching the boom direction control valve 23, and an arm direction control valve 26 for switching the arm direction control valve 24.

  The boom operating device 25 is connected to the pilot pump 22 and supplies the pilot pressure generated in response to the operation to the control port of the boom direction control valve 23 via one of the pilot lines 25a and 25b. The direction control valve 23 is switched to the left position or the right position in FIG. Similarly, the arm operating device 26 is also connected to the pilot pump 22 and supplies the pilot pressure generated according to the operation to the control port of the arm directional control valve 24 via either of the pilot pipe lines 26a and 26b. The arm direction control valve 24 is switched to the left position or the right position in FIG.

  Further, according to the present embodiment, when the pressure in the rod chamber 6b of the boom cylinder 6 becomes higher than a predetermined pressure, the switching valve 57 that connects the rod chamber 6b of the boom cylinder 6 and the bottom chamber 7a of the arm cylinder 7 is communicated. Including a communication control unit.

  As shown in FIG. 2, the communication control unit is provided in the communication path 40 that can communicate the rod chamber 6 b of the boom cylinder 6 and the bottom chamber 7 a of the arm cylinder 7, and the boom cylinder 6. The switching valve 57 that shuts off the communication passage 40 when the pressure in the rod chamber 6b is lower than a predetermined pressure and holds the communication passage 40 in a communication state when the pressure is higher than a predetermined pressure is included. The switching valve 57 is composed of a pilot-type switching valve that is switched by a pilot pressure guided through a pipe line 57b. Further, a check valve 41 is included that prevents the flow of pressure oil from the bottom chamber 7a of the arm cylinder 7 toward the rod chamber 6b of the boom cylinder 6. An overload relief valve 80 is provided on a pipe line 56 connecting the rod chamber 6 b of the boom cylinder 6 and the tank 43. The set pressure by the spring 57a for switching the switching valve 57 from the shut-off position to the communication position is set to be lower than the set pressure of the overload relief valve 80.

  Further, the hydraulic drive device according to the present embodiment includes a first pressure detection unit that detects the rod pressure of the boom cylinder 6, that is, a first pressure sensor 67 d, and a second pressure detection unit that detects the bottom pressure of the arm cylinder 7, That is, a second pressure sensor 67c is provided. Further, in the present embodiment, when the differential pressure ΔP between the rod pressure of the boom cylinder 6 detected by the first pressure sensor 67d and the bottom pressure of the arm cylinder 7 detected by the second pressure sensor 67c is equal to or greater than a predetermined pressure S. In addition, an opening control unit for controlling the switching valve 57 so as to reduce the opening area is provided.

  In the present embodiment, the operation amount of the first operation amount detection unit that detects the operation amount of the boom operation device 25 when raising the boom, that is, the third pressure sensor 67b, and the operation amount of the arm operation device 26 when the arm cloud is used. A second operation amount detection unit to detect, that is, a fourth pressure sensor 67a is provided.

  Further, in the present embodiment, the pilot pressure for controlling the opening area of the switching valve 57 to the control port of the switching valve 57 via the pilot pipe line 57b, that is, the pilot pressure based on the pilot pump 22 guided via the pipe line 69a. Is provided.

  The opening control unit described above includes a controller 68 that outputs a control signal for controlling the electromagnetic valve 69. When the rod pressure of the boom cylinder 6 is lower than the predetermined pressure, the value of the control signal output from the controller 68 to the solenoid valve 69 is small, and the force by the pilot pressure guided to the pilot pipe line 57b is the force of the spring 57a of the switching valve 57. Keeps weaker than power. As a result, the switching valve 57 is maintained at the left position in FIG. 2, and the communication path 40 is blocked. Therefore, in this state, the pressure oil from the rod chamber 6 b of the boom cylinder 6 is not supplied to the bottom chamber 57 a of the arm cylinder 57. Further, when the rod pressure of the boom cylinder 6 becomes higher than a predetermined pressure, the value of the control signal output from the controller 68 to the electromagnetic valve 69 increases, and the force by the pilot pressure guided to the pilot line 57b is changed over to the switching valve. It becomes stronger than the force of the 57 spring 57a. As a result, the switching valve 57 is switched to the right position in FIG. 2, and the communication path 40 communicates. Therefore, in this state, the pressure oil from the rod chamber 6 b of the boom cylinder 6 can be regenerated and supplied to the bottom chamber 7 a of the arm cylinder 7.

  As shown in FIG. 3, the controller 68 provided in the present embodiment includes a detection signal of a third pressure sensor 67b that detects an operation amount of the boom operation device 25 when raising the boom, and an arm operation device when the arm cloud is used. Whether the detection signal of the fourth pressure sensor 67a for detecting the operation amount of 26 is input, and both the boom operation device 25 and the arm operation device 26 are operated to perform the boom raising / arm cloud combined operation. A determination unit 93 for determining whether or not and a calculation unit for obtaining a differential pressure ΔP between the rod pressure of the boom cylinder 6 detected by the fourth pressure sensor 67d and the bottom pressure of the arm cylinder 6 detected by the second pressure sensor 67c. 90 and when the differential pressure ΔP obtained by the calculation unit 90 is equal to or higher than a predetermined pressure S, the opening area of the switching valve 57 is smaller than the maximum. The first function generator 91 is set so as to output an opening area that becomes a mouth, that is, an opening area smaller than the maximum opening area M. Further, as shown in FIG. 3, in the present embodiment, when the determination unit 93 determines that both the boom operation device 25 and the arm operation device 26 are operated, the opening area control of the switching valve 57 is controlled. When the control of the opening area of the switching valve 57 is permitted by the switching unit 92, that is, when the switching unit 92 is turned on, the first function is generated. And an output unit 94 that outputs a control signal having a value corresponding to the opening area obtained by the unit 91 to the electromagnetic valve 69.

  The first function generator 91 described above maintains the maximum opening area M until the differential pressure ΔP reaches the predetermined pressure S. When the differential pressure ΔP exceeds the predetermined pressure S, the opening area gradually decreases as the differential pressure ΔP increases. Set to relationship. Further, the output unit 94 is set to have a relationship in which the value is gradually increased until the opening area reaches the maximum opening area M, and the control signal having the maximum value is set above the maximum opening area M. .

  In the present invention configured as described above, when excavation work as shown in FIG. 1 is performed by boom raising and arm cloud combined operation, the boom operation device 25 is operated in the right direction in FIG. Is operated in the right direction of FIG. The pilot pressure is guided to the pilot line 25a by the operation of the boom operation device 25, the boom direction control valve 23 is switched to the left position in FIG. 2, and the pilot pressure is changed by the operation of the arm operation device 26. 26a, the arm direction control valve 24 is switched to the left position in FIG. At this time, the operation of the boom operation device 25 is detected by the third pressure sensor 67 b, the operation of the arm operation device 26 is detected by the fourth pressure sensor 67 a, and the respective detection signals are output to the controller 68.

  As described above, when the boom direction control valve 23 is switched to the left position in FIG. 2, the pressure oil discharged from the hydraulic pump 21 passes through the conduit 28, the boom direction control valve 23, and the main conduit 29b. The pressure oil supplied to the bottom chamber 6a of the boom cylinder 6 and discharged from the rod chamber 6b of the boom cylinder 6 is returned to the tank 43 via the main conduit 29b, the boom direction control valve 23, and the conduit 42. As a result, the boom cylinder 6 extends as shown by the arrow 13 in FIG. 1, and the boom 3 rotates in the direction of the arrow 12 in FIG. 1 to raise the boom.

  2 is switched to the left position in FIG. 2, the pressure oil discharged from the hydraulic pump 21 is supplied to the conduit 27, the arm direction control valve 24, Pressure oil supplied to the bottom chamber 7a of the arm cylinder 7 through the main pipe line 30a and discharged from the rod chamber 7b of the arm cylinder 7 is returned to the tank 43 through the main pipe line 30b and the arm direction control valve 24. . As a result, the arm cylinder 7 extends as shown by the arrow 9 in FIG. 1, and the arm 4 rotates in the direction of the arrow 11 in FIG.

  As shown in FIG. 1, excavation work by the bucket 5 is performed by the combined operation of the boom raising operation and the arm cloud operation as described above.

  In such a boom raising and arm cloud combined operation, the rod pressure of the boom cylinder 6 is detected by the first pressure sensor 67d, the bottom pressure of the arm cylinder 7 is detected by the second pressure sensor 67c, and each detection signal is sent to the controller. 68 is output.

  A detection signal is output from the third pressure sensor 67b to the controller 68 when the boom operation device 25 is operated as described above, and the fourth pressure is generated when the arm operation device 26 is operated. When a detection signal is output from the sensor 67a to the controller 68, the determination unit 93 of the controller 68 operates both the boom operation device 25 and the arm operation device 26 to perform the boom raising / arm cloud combined operation. It determines that it is in a state, and outputs a signal for turning on the switching unit 92. As a result, the first function generator 91 and the output unit 94 are communicated with each other via the switching unit 92. Note that the switching unit 92 is kept off under the control of the determination unit 93 during an operation other than the boom raising / arm cloud combined operation. Therefore, in such a case, the control based on the opening area of the first function generator 91 is not performed.

  Further, based on the detection signal of the first pressure sensor 67d that detects the rod pressure of the boom cylinder 6 and the detection signal of the second pressure sensor 67c that detects the bottom pressure of the arm cylinder 7, the controller 68 shown in FIG. The calculation unit 90 performs a calculation for subtracting the bottom pressure of the arm cylinder 7 from the rod pressure of the boom cylinder 6 to obtain the differential pressure ΔP. The obtained differential pressure ΔP is output to the first function generator 91.

  During the boom raising / arm cloud combined operation, the maximum opening area M is output from the first function generator 91 when the above-described differential pressure ΔP does not reach the predetermined pressure S set by the first function generator 91. The maximum opening area M is output to the output unit 94 via the switching unit 92. The output unit 94 outputs a control signal having a large value corresponding to the maximum opening area M to the electromagnetic valve 69 shown in FIG.

  As shown in FIG. 2, the electromagnetic valve 69 operates so as to supply the maximum pilot pressure to the pilot line 57b in response to a large value control signal. At this time, the force due to the pilot pressure is larger than the force of the spring 57a. Therefore, the switching valve 57 is switched to the right position in FIG. As a result, the pressure oil discharged from the bottom chamber 6b of the boom cylinder 6 flows into the bottom of the arm cylinder 7 via the main pipeline 29b, the pipeline 56, the switching valve 57, the check valve 41, the pipeline 40, and the main pipeline 30a. Regeneration is supplied to the chamber 7a, and the speed of the arm cylinder 7 can be increased.

  When the differential pressure ΔP between the rod pressure of the boom cylinder 6 and the bottom pressure of the arm cylinder 7 obtained by the calculation unit 90 of the controller 68 increases to exceed a predetermined pressure S, the opening area output from the first function generation unit 91 is , Smaller than the maximum opening area M. A signal corresponding to the small opening area is sent from the first function generator 91 to the output unit 94 via the switching unit 92. The output unit 94 outputs a control signal having a relatively small value corresponding to the opening area smaller than the maximum opening area to the electromagnetic valve 69.

  The electromagnetic valve 69 operates to supply a pilot pressure smaller than the maximum pilot pressure to the pilot line 57b in response to a control signal having a relatively small value. In response to this, the switching valve 57 tends to be switched to the left position side in FIG. 2, and the opening area of the stiffness switching valve 57 is a relatively small opening area obtained by the first function generator 91 of the controller 68. It is controlled to become.

  The oil discharged from the rod chamber 6b of the boom cylinder 6 is regenerated in the bottom chamber 7a of the arm cylinder 7 through the switching valve 57, the communication passage 40, and the like controlled to have a relatively small opening area.

  As described above, in the present embodiment, in the boom raising / arm cloud combined operation, the rod pressure of the boom cylinder 6 detected by the first pressure sensor 67d and the bottom pressure of the arm cylinder 7 detected by the second pressure sensor 67c. When the pressure difference ΔP is detected to be equal to or greater than the predetermined pressure S, the controller 68 constituting the opening control unit including the calculation unit 90, the first function generation unit 91, the determination unit 93, etc. The switching valve 57 is controlled to be smaller. That is, the flow rate of the pressure oil that is sent from the rod chamber 6b of the boom cylinder 9 to the bottom chamber 7a of the arm cylinder 6 through the switching valve 57 is smaller than when the switching valve 57 is held at the maximum opening area M. . As a result, when the boom is raised and the arm cloud is combined, the shock generated in the airframe according to the differential pressure ΔP between the rod pressure of the boom cylinder 6 and the bottom pressure of the arm cylinder 7 can be suppressed, and the operability can be improved. It is possible to ensure high working accuracy.

  FIG. 4 is a block diagram showing a main configuration of a controller provided in another embodiment of the present invention.

  As shown in FIG. 4, in the second embodiment of the hydraulic drive device according to the present invention, the controller 68 has a third pressure corresponding to the operation amount of the boom operation device 25 in addition to the configuration of the first embodiment. The second function generator 95 in which the relationship between the pressure Pa detected by the sensor 67b and the opening area is set, and the pressure Pb detected by the fourth pressure sensor 67a corresponding to the operation amount of the arm operating device 26 The minimum value of the opening area output from each of the third function generator 96, the first function generator 91, the second function generator 95, and the third function generator 96 for which the relationship with the opening area is set. A minimum value selection unit 97 that selects and outputs to the switching unit 92 is included. Other configurations are the same as those of the first embodiment described above.

  The relationship between the pressure Pa and the opening area in the second function generating unit 95 and the relationship between the pressure Pb and the opening area in the third function generating unit 96 are relationships that are considered to be empirically desirable when excavation work is performed, for example. Yes. The second function generation unit 95 maintains the maximum opening area while the operation amount of the boom operation device 25 is relatively small and the pressure Pa output from the second pressure sensor 67b is less than the predetermined pressure A. When A is greater than or equal to A, the opening area is smaller than the maximum opening area. On the contrary, the third function generator 96 maintains the opening area smaller than the maximum opening area while the operation amount of the arm operating device 26 is relatively small and does not reach the predetermined pressure B. When the device 26 is greatly operated and becomes a predetermined pressure B or more, the maximum opening area is established.

  By providing the second function generating unit 95 and the third function generating unit 96 in the controller 68, excavation work is performed by a boom raising / arm cloud combined operation, and the excavated earth and sand are loaded on a dump truck or the like. In this case, when the boom raising operation device 25 is largely operated, the opening area 0 is output from the minimum value selection unit 97 to the output unit 94 via the switching unit 92 even when the arm cloud operation is performed at the same time, as shown in FIG. The switching valve 57 is held at the left position in FIG. 2, that is, at a position where the communication path 40 is blocked. Further, when the arm operation device 26 is operated to be small in order to perform the inching operation of the arm 4, even when the boom raising operation is performed at the same time, the opening area 0 is output from the minimum value selection unit 97 via the switching unit 92. 94, and the switching valve 57 is held at a position where the communication path 40 is blocked. That is, it is set so that playback is not performed when the above operation is performed.

  Further, for example, the operation amount of the boom raising operation of the boom operation device 25 is set such that the pressure Pa detected by the third pressure sensor 67 b is slightly larger than the predetermined pressure A set by the second function generator 95. And the operation amount of the arm operating device 26 is an operation amount in which the pressure Pb detected by the fourth pressure sensor 67a is slightly smaller than the predetermined pressure B set by the third function generator 96. In some cases, when the differential pressure ΔP between the bottom pressure of the boom cylinder 6 and the rod pressure of the arm cylinder 7 is smaller than the predetermined pressure S set by the first function generator 9, a relatively large opening area is minimized. The value is output from the value selection unit 97 to the output unit 94 via the switching unit 92. Accordingly, the switching valve 52 tends to be switched to the right position side in FIG. 2, and the oil discharged from the rod chamber 6 b of the boom cylinder 6 through the communication path 40 is supplied to the bottom chamber 7 b of the arm cylinder 7. The arm cylinder 7 can be increased in speed. Other basic functions and effects are the same as those of the first embodiment.

  In the second embodiment as well, the controller 68 constituting the aperture control unit includes a calculation unit 90, a first function generation unit 91, a switching unit 92, a determination unit 93, and an output unit 94 equivalent to those in the first embodiment. Therefore, similarly to the first embodiment, during the boom raising / arm cloud combined operation, the shock generated in the airframe is suppressed according to the differential pressure ΔP between the rod pressure of the boom cylinder 6 and the bottom pressure of the arm cylinder 7. And operability can be improved. In particular, in the second embodiment, the controller 68 has a minimum value together with the second function generation unit 95 and the third function generation unit 96 in which the relationship considering the boom raising / arm cloud combined operation expected in excavation work is set. Since the selection unit 97 is included, it is possible to ensure high work accuracy during excavation work and to suppress shock of the airframe during excavation work.

DESCRIPTION OF SYMBOLS 1 Traveling body 2 Revolving body 3 Boom 4 Arm 6 Boom cylinder 6a Bottom chamber 6b Rod chamber 7 Arm cylinder 7a Bottom chamber 7b Rod chamber 21 Main hydraulic pump 22 Pilot pump 23 Boom direction control valve 24 Arm direction control valve 25 Boom Operating device 26 Arm operating device 40 Communication path 57 Switching valve 57a Spring 57b Pilot pipe line 67a Fourth pressure sensor (second operation amount detection unit)
67b 3rd pressure sensor (1st operation amount detection part)
67c 2nd pressure sensor (2nd pressure detection part)
67d 1st pressure sensor (1st pressure detection part)
68 Controller (Aperture control unit)
69 Solenoid valve 90 Calculation unit 91 First function generation unit 92 Switching unit (permission unit)
93 Discrimination Unit 94 Output Unit 95 Second Function Generation Unit 96 Third Function Generation Unit 97 Minimum Value Selection Unit

Claims (4)

A main hydraulic pump, a boom cylinder and an arm cylinder driven by pressure oil discharged from the main hydraulic pump and having a rod chamber and a bottom chamber, respectively, and a flow of pressure oil supplied from the main hydraulic pump to the boom cylinder Direction control valve for controlling the boom, the direction control valve for arm for controlling the flow of pressure oil supplied from the main hydraulic pump to the arm cylinder, and the operation device for boom for switching the direction control valve for boom And the arm operating device for switching the arm direction control valve, and the rod chamber of the boom cylinder and the arm cylinder when the pressure of the rod chamber of the boom cylinder becomes higher than a predetermined pressure. In the hydraulic drive device of a hydraulic excavator provided with a switching valve for communicating with the bottom chamber of
A first pressure detector for detecting the rod pressure of the boom cylinder; a second pressure detector for detecting a bottom pressure of the arm cylinder;
When the differential pressure between the rod pressure of the boom cylinder detected by the first pressure detector and the bottom pressure of the arm cylinder detected by the second pressure detector is equal to or higher than a predetermined pressure, the boom cylinder A hydraulic drive device for a hydraulic excavator, comprising: an opening control unit that controls the switching valve so that an opening area of the switching valve that communicates the rod chamber with the bottom chamber of the arm cylinder is reduced. In the hydraulic drive device of the hydraulic excavator according to claim 1,
A first operation amount detection unit that detects an operation amount of the boom operation device when the boom is raised, and a second operation amount detection unit that detects an operation amount of the arm operation device when the arm is clouded,
The opening controller is
Whether the boom operating device and the arm operating device are respectively raised in the boom and operated by the arm cloud in response to signals output from the first operation amount detecting unit and the second operation amount detecting unit. A determination unit for determining
A calculation unit for obtaining a differential pressure between the rod pressure of the boom cylinder detected by the first pressure detection unit and the bottom pressure of the arm cylinder detected by the second pressure detection unit;
A first function generator configured to output an opening area such that the opening area of the switching valve is smaller than the maximum when the differential pressure obtained by the calculation unit is equal to or greater than the predetermined pressure. ,
The opening control unit outputs an opening area output from the first function generating unit when the determining unit determines that the boom operating device and the arm operating device have respectively raised the boom and operated the arm cloud. A hydraulic drive device for a hydraulic excavator, wherein the switching valve is controlled according to The hydraulic drive device for a hydraulic excavator according to claim 2,
The opening controller is
A second function generation unit in which the relationship between the operation amount of the first operation amount detection unit and the opening area is set;
A third function generation unit in which the relationship between the operation amount of the second operation amount detection unit and the opening area is set;
A minimum value selection unit that selects a minimum value of the opening area respectively output from the first function generation unit, the second function generation unit, and the third function generation unit;
The opening control unit determines the opening area output from the minimum value selection unit when the determination unit determines that the boom operation device and the arm operation device are respectively raised and operated by the boom. A hydraulic drive device for a hydraulic excavator, wherein the switching valve is controlled to be The hydraulic drive device for a hydraulic excavator according to claim 3 ,
The first pressure detection unit includes a first pressure sensor, the second pressure detection unit includes a second pressure sensor, the first operation amount detection unit includes a third pressure sensor, and the second operation amount detection unit. Consists of a fourth pressure sensor,
The control port of the switching valve includes a solenoid valve capable of supplying a pilot pressure for controlling the opening area of the switching valve,
The opening control unit includes a controller that outputs a control signal for controlling the electromagnetic valve. The controller includes the determination unit, the calculation unit, the first function generation unit, and the second function generation unit. And the third function generation unit and the minimum value selection unit, and the determination unit determines that the boom operation device and the arm operation device are respectively raised and operated by the boom. A permitting unit that permits the control of the opening area of the switching valve, and an opening area that is output from the minimum value selecting unit when the permitting unit permits the control of the opening area of the switching valve. A hydraulic drive device for a hydraulic excavator, comprising: an output unit that outputs a control signal corresponding to the above to the electromagnetic valve.

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