JP2018105080A - Hydraulic system of working machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable the output of predetermined hydraulic equipment to be easily reduced.SOLUTION: A hydraulic system of a working machine comprises: a hydraulic pump for delivering hydraulic fluid; hydraulic equipment which can be operated by the hydraulic fluid; an operation member for operating the hydraulic equipment; a plurality of operation valves which can change a pressure of the hydraulic fluid in accordance with the operation of the operation member; a discharge oil passage which is communicated with at least one of the operation valves and discharges the hydraulic fluid; and an actuation valve which is provided in the discharge oil passage and can reduce the pressure of the hydraulic fluid in the discharge oil passage.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a hydraulic system for a work machine such as a skid steer loader or a compact truck loader.

  Conventionally, it is necessary to reduce the output of hydraulic equipment or the like in a work machine due to various circumstances. For example, in Patent Document 1, when a load greater than a predetermined value is applied to the engine, the output of a traveling pump, which is one of hydraulic devices, is reduced. Specifically, the working machine of Patent Document 1 includes an engine, a travel pump driven by the engine, a travel operation lever, and an operation valve that can change the pressure of the pilot oil (pilot pressure) according to the operation of the travel operation lever. And a pressure control valve provided on the upstream side of the operation valve.

Japanese Patent No. 5687970

  In the working machine of Patent Document 1, when a load exceeding a predetermined value is applied to the engine, the pressure of the hydraulic oil (primary pressure) entering the operation valve is operated by operating a pressure control valve arranged on the upstream side of the operation valve. This reduces the output of the traveling pump. As described above, when the pressure on the primary side of the operation valve is reduced as a method of reducing the output of the traveling pump, etc., all hydraulic devices connected to the operation valve, that is, devices other than the traveling pump, do not want to decrease the output. The output of the hydraulic equipment will also decrease.

  The present invention has been made to solve the above-described problems of the prior art, and provides a hydraulic system for a working machine that can easily reduce the pressure of an oil passage connected to a hydraulic device or the like. With the goal.

The technical means of the present invention for solving this technical problem is as follows.
The hydraulic system of the work machine includes a hydraulic pump that discharges hydraulic oil, a hydraulic device that can be operated by the hydraulic oil, an operation member that operates the hydraulic device, and a pressure of the hydraulic oil that changes according to the operation of the operation member A plurality of possible operation valves, a discharge oil passage communicating with at least one of the plurality of operation valves and discharging the hydraulic oil, and a pressure of the hydraulic oil provided in the discharge oil passage and in the discharge oil passage And an actuating valve capable of reducing the pressure.

  A hydraulic system for a work machine includes a hydraulic pump that discharges hydraulic oil, a hydraulic device that can be operated by hydraulic oil, a first operating member that can be operated in one direction and the other direction, and a one-way operation of the first operating member. A first operation valve capable of changing the pressure of the hydraulic oil according to the operation, and a second operation valve capable of changing the pressure of the hydraulic oil according to an operation in the other direction of the first operation member. A first operating device that is different from the first operating device, a second operating member that can be operated in one direction and the other direction, and hydraulic oil in response to an operation in one direction of the second operating member A second operating device that has a third operating valve that can change the pressure of the second operating member and a fourth operating valve that can change the pressure of the hydraulic oil in response to an operation in the other direction of the second operating member. And at least one of the first operation valve, the second operation valve, the third operation valve, and the fourth operation valve It comprises a discharge oil passage for discharging the communicating and hydraulic oil, provided in the discharge oil passage, and, a, and actuated valve capable reducing the pressure of the working oil in the discharge oil passage to.

The operating valve has a relief valve whose set pressure can be changed.
The operating valve includes a proportional valve that is connected to the pressure receiving portion of the relief valve and can change the set pressure by changing the pressure of hydraulic oil that acts on the pressure receiving portion.
A hydraulic system for a work implement includes a second oil passage that connects the first operation valve, the second operation valve, a third operation valve, and a fourth operation valve to the hydraulic device, and that is connected to the discharge oil passage. And is provided in the discharge oil passage, and allows the operation oil to flow from the second oil passage toward the operation valve and prevents the operation oil from flowing from the discharge side toward the second oil passage. And a check valve.

A hydraulic system for a work machine connects a plurality of operation valves and the hydraulic device, and is provided in a second oil passage to which the discharge oil passage is connected, and in the discharge oil passage, from the second oil passage. A check valve that allows the working oil to flow toward the working valve and prevents the working oil from flowing from the discharge side toward the second oil passage.
The operating valve has a pilot check valve capable of preventing the hydraulic oil from being discharged from the discharge oil passage based on the pressure of the hydraulic oil acting on the pressure receiving portion.

The operating valve has a switching valve that can be switched between a first position that allows the hydraulic oil to be discharged in the exhaust oil passage and a second position that prevents the hydraulic oil from being discharged in the exhaust oil passage.
The hydraulic device is a traveling pump whose output changes depending on the pressure of hydraulic oil.

  According to the present invention, it is possible to easily reduce the pressure of an oil passage connected to a hydraulic device or the like.

1 is a schematic diagram of a traveling hydraulic system. FIG. It is the schematic of the hydraulic system of a working system. It is a figure which shows the 1st modification of a hydraulic system. It is a figure which shows the 2nd modification of a hydraulic system. It is a side view which shows the track loader which is an example of a working machine. It is a side view which shows a part of track loader of the state which raised the cabin.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 4 shows a side view of the working machine according to the present invention. FIG. 4 shows a compact truck loader as an example of a work machine. However, the working machine according to the present invention is not limited to the compact truck loader loader, and may be another type of loader working machine such as a skid steer loader. Moreover, a working machine other than the loader working machine may be used.

  As shown in FIGS. 4 and 5, the work machine 1 includes a machine body 2, a cabin 3, a work device 4, and a traveling device 5. In the embodiment of the present invention, the front side (the left side in FIG. 4) of the driver seated on the driver's seat 8 of the work machine 1 is the front side, the rear side (the right side in FIG. 4) is the rear side, and the left side (the figure) The description will be made assuming that the front side of FIG. The horizontal direction, which is a direction orthogonal to the front-rear direction, will be described as the body width direction. The direction from the central part of the airframe 2 toward the right part or the left part will be described as the outside of the airframe. In other words, the outward direction of the body is the direction of the body width and away from the body 2. The direction opposite to the outside of the aircraft will be described as the inside of the aircraft. In other words, the in-machine direction is the width direction of the machine body and the direction approaching the machine body 2.

The cabin 3 is mounted on the airframe 2. The cabin 3 is provided with a driver's seat 8. The work device 4 is attached to the machine body 2. The traveling device 5 is provided outside the airframe 2. A prime mover is mounted at the rear of the body 2.
The work device 4 includes a boom 10, a work tool 11, a lift link 12, a control link 13, a boom cylinder 14, and a bucket cylinder 15.

  The boom 10 is provided on the right and left sides of the cabin 3 so as to be swingable up and down. The work tool 11 is, for example, a bucket, and the bucket 11 is provided at the tip (front end) of the boom 10 so as to be swingable up and down. The lift link 12 and the control link 13 support the base part (rear part) of the boom 10 so that the boom 10 can swing up and down. The boom cylinder 14 raises and lowers the boom 10 by expanding and contracting. The bucket cylinder 15 swings the bucket 11 by expanding and contracting.

The front portions of the left and right booms 10 are connected to each other by a deformed connection pipe. The bases (rear parts) of the booms 10 are connected by a circular connection pipe.
The lift link 12, the control link 13, and the boom cylinder 14 are respectively provided on the left side and the right side of the body 2 corresponding to the left and right booms 10.
The lift link 12 is provided in the longitudinal direction at the rear of the base of each boom 10. The upper portion (one end side) of the lift link 12 is pivotally supported around the horizontal axis via a pivot shaft 16 (first pivot shaft) near the rear portion of the base of each boom 10. Further, the lower portion (the other end side) of the lift link 12 is pivotally supported around the horizontal axis via a pivot shaft 17 (second pivot shaft) near the rear portion of the machine body 2. The second pivot shaft 17 is provided below the first pivot shaft 16.

  The upper part of the boom cylinder 14 is pivotally supported about a horizontal axis via a pivot shaft 18 (third pivot shaft). The third pivot shaft 18 is a base portion of each boom 10 and is provided at the front portion of the base portion. The lower part of the boom cylinder 14 is pivotally supported around a horizontal axis via a pivot shaft 19 (fourth pivot shaft). The fourth pivot shaft 19 is provided near the lower part of the rear part of the machine body 2 and below the third pivot shaft 18.

  The control link 13 is provided in front of the lift link 12. One end of the control link 13 is pivotally supported about a horizontal axis via a pivot shaft 20 (fifth pivot shaft). The fifth pivot shaft 20 is the body 2 and is provided at a position corresponding to the front of the lift link 12. The other end of the control link 13 is pivotally supported about a horizontal axis via a pivot shaft 21 (sixth pivot shaft). The sixth pivot shaft 21 is the boom 10 and is provided in front of the second pivot shaft 17 and above the second pivot shaft 17.

  By expanding and contracting the boom cylinder 14, each boom 10 swings up and down around the first pivot shaft 16 while the base of each boom 10 is supported by the lift link 12 and the control link 13, and the tip of each boom 10 is Goes up and down. The control link 13 swings up and down around the fifth pivot shaft 20 as each boom 10 swings up and down. The lift link 12 swings back and forth around the second pivot shaft 17 as the control link 13 swings up and down.

Another work tool can be attached to the front portion of the boom 10 instead of the bucket 11. Another working tool is an attachment (preliminary attachment) such as a hydraulic crusher, a hydraulic breaker, an angle bloom, an earth auger, a pallet fork, a sweeper, a mower, and a snow blower.
A connecting member 50 is provided at the front of the left boom 10. The connection member 50 is a device that connects the hydraulic equipment equipped in the preliminary attachment to the first pipe material such as a pipe provided in the boom 10. Specifically, the first pipe member can be connected to one end of the connecting member 50, and the second pipe member connected to the hydraulic device of the preliminary attachment can be connected to the other end. Thereby, the hydraulic oil flowing through the first pipe material passes through the second pipe material and is supplied to the hydraulic equipment.

The bucket cylinder 15 is arranged near the front part of each boom 10. By expanding and contracting the bucket cylinder 15, the bucket 11 is swung.
Each of the left and right traveling devices 5 is a crawler type (including a semi-crawler type) traveling device in this embodiment. In addition, you may employ | adopt the wheel type traveling apparatus which has a front wheel and a rear wheel.

Next, a traveling hydraulic system will be described.
As shown in FIG. 1, the hydraulic system includes a first hydraulic pump P1, a left travel motor device (first travel motor device) 31L, a right travel motor device (second travel motor device) 31R, a prime mover 32, And a travel drive device 34.
The first hydraulic pump P1 can discharge the hydraulic oil stored in the tank 22. The first hydraulic pump P1 is a drive pump driven by the power of the prime mover, and is constituted by a constant capacity type gear pump. The first hydraulic pump P1 discharges hydraulic oil mainly used for control. For convenience of explanation, the tank 22 that stores hydraulic oil may be referred to as a hydraulic oil tank. Of the hydraulic oil discharged from the first hydraulic pump P1, the hydraulic oil used for control may be called pilot oil, and the pressure of the pilot oil may be called pilot pressure. An oil passage (discharge oil passage) 40 through which hydraulic oil (pilot oil) flows is provided on the discharge side of the first hydraulic pump P1. The discharge oil passage (first oil passage) 40 is provided with a first traveling motor device 31L and a second traveling motor device 31R.

The prime mover 32 includes an electric motor, an engine, and the like. In this embodiment, the prime mover 32 is an engine. The prime mover 32 may be a hybrid type having an electric motor and an engine, or may have only an electric motor.
The travel drive device 34 is a device that drives the first travel motor device 31L and the second travel motor device 31R, and includes a drive circuit (left drive circuit) 34L for driving the first travel motor device 31L and a second travel. And a drive circuit (right drive circuit) 34R for driving the motor device 31R.

  The left drive circuit 34L and the right drive circuit 34R have travel pumps (travel hydraulic pumps) 53L and 53R, speed change oil passages 57h and 57i, and a second charge oil passage 57j, respectively. The speed change oil passages 57h and 57i are oil passages that connect the travel pumps 53L and 53R to the travel motor 36. The second charge oil passage 57j is an oil passage that is connected to the transmission oil passages 57h and 57i and replenishes the hydraulic oil from the first hydraulic pump P1 to the transmission oil passages 57h and 57i.

  The traveling pumps 53L and 53R are swash plate type variable displacement axial pumps driven by the power of the prime mover 32. The traveling pumps 53L, 53R have a forward pressure receiving portion 53a and a reverse pressure receiving portion 53b on which pilot pressure acts. The angle of the swash plate is changed by the pilot pressure acting on the forward pressure receiving portion 53a and the reverse pressure receiving portion 53b. By changing the angle of the swash plate, it is possible to change the output (discharge amount of hydraulic oil) of the traveling pumps 53L and 53R and the discharge direction of the hydraulic oil.

The first travel motor device 31L is a motor that transmits power to the drive shaft of the travel device 5 provided on the left side of the machine body 2. The second traveling motor device 31 </ b> R is a motor that transmits power to the drive shaft of the traveling device 5 provided on the right side of the machine body 2.
The first travel motor device 31L includes a travel motor 36, a front / rear switching valve 35, and a travel control valve (hydraulic switching valve) 38. Hydraulic fluid can be supplied to the travel motor 36, the front / rear switching valve 35, and the travel control valve 38.

  The travel motor 36 is a cam motor (radial piston motor). The travel motor 36 changes the rotation and torque of the output shaft by varying the capacity (motor capacity) during operation. Specifically, the travel motor 36 includes a first motor 36A and a second motor 36B. By driving the first motor 36A and the second motor 36B, the motor capacity is increased and the traveling motor 36 is set to the first speed. Further, by driving either the first motor 36A or the second motor 36B, the motor capacity is reduced, and the traveling motor 36 is in the second speed.

  The travel control valve 38 is a two-position switching valve that switches to a first position 38a and a second position 38b. The switching operation of the travel control valve 38 is performed by the switch 91 or the like. Specifically, the switch 91 is connected to the control device 90, and when the first speed is set by the switch 91, the control device 90 is connected to the pressure receiving portion of the travel control valve 38 via an oil passage. The traveling control valve 38 is switched to the second position 38b by switching the hydraulic switching valve. When the second speed is set by the switch 91, the control device 90 switches the travel control valve 38 to the first position 38a by switching the hydraulic switching valve. As described above, the speed of the traveling motor 36 (the first motor 36A and the second motor 36B) can be changed by switching the traveling control valve 38.

Next, a working hydraulic system will be described.
As shown in FIG. 2, the hydraulic system includes a plurality of control valves 56 and a work system hydraulic pump (second hydraulic pump) P2.
The second hydraulic pump P2 is a pump installed at a position different from the first hydraulic pump P1, and is constituted by a constant capacity type gear pump. The second hydraulic pump P <b> 2 can discharge the hydraulic oil stored in the hydraulic oil tank 22. The second hydraulic pump P2 mainly discharges hydraulic oil that operates the hydraulic actuator.

  An oil passage (main oil passage) 39 is provided on the discharge side of the second hydraulic pump P2. A plurality of control valves 56 are connected to the main oil passage 39. The control valve 56 is a valve capable of switching the flow direction of the hydraulic oil by the pilot pressure of the pilot oil. The control valve 56 controls (drives) a hydraulic device such as a boom, bucket, hydraulic crusher, hydraulic breaker, angle bloom, earth auger, pallet fork, sweeper, mower, snow blower, and the like.

  The plurality of control valves 56 are a first control valve 56A, a second control valve 56B, and a third control valve 56C. The first control valve 56A is a valve that controls a hydraulic cylinder (boom cylinder) 14 that controls the boom. The second control valve 56B is a valve that controls a hydraulic cylinder (bucket cylinder) 15 that controls the bucket. The third control valve 56C is a valve that controls hydraulic equipment (hydraulic cylinder, hydraulic motor) mounted on a spare attachment such as a hydraulic crusher, a hydraulic breaker, an angle bloom, an earth auger, a pallet fork, a sweeper, a mower, and a snow blower. is there.

  The first control valve 56A and the second control valve 56B are pilot-type direct acting spool type three-position switching valves, respectively. The first control valve 56A and the second control valve 56B are switched to the neutral position, the first position different from the neutral position, the neutral position, and the second position different from the first position by the pilot pressure. The boom cylinder 14 is connected to the first control valve 56A via an oil passage, and the bucket cylinder 15 is connected to the second control valve 56B via an oil passage.

  A supply / discharge oil passage 83 is connected to the third control valve 56C. One end of the supply / discharge oil passage 83 is connected to the supply / discharge port of the third control valve 56C, a middle portion of the supply / discharge oil passage 83 is connected to the connection member 50, and the other end of the supply / discharge oil passage 83 is Connected to the hydraulic equipment of the spare attachment. Specifically, the supply / discharge oil passage 83 includes a first supply / discharge oil passage 83 a that connects the first supply / discharge port of the third control valve 56 </ b> C and the first port of the connection member 50. Further, the supply / discharge oil passage 83 includes a second supply / discharge oil passage 83b that connects the second supply / discharge port of the third control valve 56C and the second port of the connecting member 50. That is, by operating the third control valve 56C, the working oil flows from the third control valve 56C toward the first supply / discharge oil passage 83a, or from the third control valve 56C toward the second supply / discharge oil passage 83b. Hydraulic fluid.

  As shown in FIG. 1, an operation (traveling operation) related to traveling of the work machine 1 and an operation (working operation) related to work are performed on the first operating device 47 provided on the left side of the driver seat 8 and on the right side of the driver seat 8. This is performed by the second operating device 48 provided. In other words, the first operating device 47 and the second operating device 48 include a traveling hydraulic device (travel motor 36, traveling pumps 53L, 53R) and a working hydraulic device (first control valve 56A, second control valve 56B). , The third control valve 56C, the boom cylinder 14, the bucket cylinder 15, and a hydraulic cylinder and a hydraulic motor provided in the auxiliary attachment).

Next, the first operating device 47 and the second operating device 48 will be described in detail.
The first operating device 47 is a device that can perform both a traveling operation and a work operation, and includes a first operating member 54. The first operation member 54 is a lever capable of performing a first operation that moves back and forth and a second operation that moves left and right (in the body width direction) different from the front and back. In other words, the first operating member 54 is a lever that can be moved in one direction (for example, front and left) and in another direction (for example, rear and right) different from the one direction.

  In the first operation member 54, the first operation is assigned to the traveling operation, and the second operation is assigned to the work operation. That is, the first operation member 54 serves as both a travel operation member (travel operation member) and a work operation member (work operation member). The first operation member 54 is not limited to a lever as long as at least the first operation and the second operation can be performed independently.

A plurality of operation valves 55 are provided below the first operation member 54. The plurality of operation valves 55 are an operation valve 55A, an operation valve 55B, an operation valve 55C, and an operation valve 55D. The operation valve 55A, the operation valve 55B, the operation valve 55C, and the operation valve 55D are connected to the discharge oil passage 40.
The operation valve 55A is a valve that operates in the previous operation of the first operation (front and back operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the previous operation. The operation valve 55B is a valve that operates in the post-operation of the first operation (front and back operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the post-operation. That is, the operation valve 55A and the operation valve 55B are valves that are actuated by the first operation, and move corresponding to the traveling operation.

  The operation valve 55C is a valve that is operated by the left operation of the second operation (left and right operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the left operation. The operation valve 55D is a valve that is operated by the right operation of the second operation (left and right operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the right operation. That is, the operation valve 55C and the operation valve 55D are valves that are actuated by the second operation, and move corresponding to the work operation.

  The second operation device 48 is a device that can perform both a traveling operation and a work operation, and includes a second operation member 58. The second operating member 58 is a lever capable of performing a first operation that moves back and forth and a second operation that moves left and right (in the body width direction) different from the front and back. In other words, the second operating member 58 is a lever that can be moved in one direction (for example, front and left) and another direction (for example, rear and right) different from the one direction.

  In the second operation member 58, the first operation is assigned to the traveling operation, and the second operation is assigned to the work operation. That is, the second operation member 48 serves as both a travel operation member (travel operation member) and a work operation member (work operation member). The second operation member 58 is not limited to a lever as long as at least the first operation and the second operation can be performed independently.

A plurality of operation valves 59 are provided below the second operation member 58. The plurality of operation valves 59 are an operation valve 59A, an operation valve 59B, an operation valve 59C, and an operation valve 59D. The operation valve 59A, the operation valve 59B, the operation valve 59C, and the operation valve 59D are connected to the discharge oil passage 40.
The operation valve 59A is a valve that operates in the previous operation of the second operation (front and back operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the previous operation. The operation valve 59B is a valve that operates in the post-operation of the first operation (front and back operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the post-operation. That is, the operation valve 59A and the operation valve 59B are valves that are activated by the first operation, and move corresponding to the traveling operation.

  The operation valve 59C is a valve that is operated by the left operation of the first operation (left and right operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the left operation. The operation valve 59D is a valve that is operated by the right operation of the second operation (left and right operations), and the pressure of the hydraulic oil that is output changes according to the operation amount (operation) of the right operation. That is, the operation valve 59C and the operation valve 59D are valves that are actuated by the second operation, and move corresponding to the work operation.

  From the above, among the plurality of operation valves, the operation valve 55A, the operation valve 55B, the operation valve 59A, and the operation valve 59B operate in response to the traveling operation, and the operation valve 55C, the operation valve 55D, the operation valve 59C, The operation valve 59D operates corresponding to the work operation. For convenience of explanation, the operation valve 55A, the operation valve 55B, the operation valve 59A, and the operation valve 59B may be referred to as a travel operation valve. Of the travel operation valves, the operation valve 55A that operates in one direction (for example, front) of the first operation member 54 is referred to as a “first operation valve”, and the other direction (for example, rear) of the first operation member 54. The operation valve 55B that is operated by the second operation member 58 is referred to as a “second operation valve”, and the operation valve 59A that is operated in one direction (for example, the front) of the second operation member 58 is referred to as a “third operation valve”. The operation valve 59B that operates in the other direction (for example, rear) of the two operation members 58 is referred to as a “fourth operation valve”.

Next, the relationship between the travel operation valve, the work operation valve, and the hydraulic equipment will be described. Reference numerals “W1”, “W2”, “D1”, and “D2” shown in FIGS. 1 and 2 indicate connection destinations of the oil passages.
The travel operation valve and travel pumps 53L and 53R, which are one of travel-related hydraulic devices (travel hydraulic devices), are connected by a travel oil passage 45. The traveling oil path 45 includes a first traveling oil path 45a, a second traveling oil path 45b, a third traveling oil path 45c, and a fourth traveling oil path 45d. The first traveling oil passage 45a is an oil passage that connects the first operating valve 55A and the forward pressure receiving portion 53a of the traveling pump 53L. The second traveling oil passage 45b is an oil passage that connects the second operation valve 55B and the reverse pressure receiving portion 53b for the traveling pump 53L. The third traveling oil passage 45c is an oil passage that connects the third operating valve 59A and the forward pressure receiving portion 53a of the traveling pump 53R. The fourth traveling oil passage 45d is an oil passage that connects the fourth operation valve 59B and the reverse pressure receiving portion 53b for the traveling pump 53R.

  When the first operation member 54 is tilted forward, the first operation valve 55A is operated, and pilot pressure is output from the first operation valve 55A. This pilot pressure acts on the forward pressure receiving portion 53a of the traveling pump 53L. When the second operating member 58 is tilted forward, the third operating valve 59A is operated and pilot pressure is output from the third operating valve 59A. This pilot pressure acts on the forward pressure receiving portion 53a of the traveling pump 53R.

  When the first operation member 54 is tilted rearward, the second operation valve 55B is operated and pilot pressure is output from the second operation valve 55B. This pilot pressure acts on the reverse pressure receiving portion 53b for the reverse travel. When the second operation member 58 is tilted rearward, the fourth operation valve 59B is operated, and pilot pressure is output from the fourth operation valve 59B. The pilot pressure acts on the reverse pressure receiving portion 53b for the traveling pump 53R.

  Therefore, when the first operation member 54 and the second operation member 58 are swung forward, the travel motor (HST motor) 36 is positively moved at a speed proportional to the swing amount of the first operation member 54 and the second operation member 58. As a result, the work machine 1 goes straight forward. When the first operating member 54 and the second operating member 58 are swung rearward, the traveling motor 36 reverses at a speed proportional to the swinging amount of the first operating member 54 and the second operating member 58, and as a result The work machine 1 goes straight backward.

Further, when one of the first operating member 54 and the second operating member 58 is swung forward and the other is swung rearward, the left traveling motor 36 and the right traveling motor 36 are in different directions. As a result, the work machine 1 turns right or left.
As described above, by moving the first operation member 54 back and forth or by moving the second operation member 58 back and forth, it is possible to perform a traveling operation for moving the work implement 1 forward, backward, right turn, and left turn.

  In addition, the work operation valve and a control valve 56 that is one of work-related hydraulic devices (work hydraulic devices) are connected by a work oil passage 46. The working oil passage 46 includes a first working oil passage 46a, a second working oil passage 46b, a third working oil passage 46c, and a fourth working oil passage 46d. The first working oil passage 46a is an oil passage that connects the operation valve 55C and the pressure receiving portion of the first control valve 56A. The second working oil passage 46b is an oil passage that connects the operation valve 55D and the pressure receiving portion of the first control valve 56A. The third working oil passage 46c is an oil passage that connects the operation valve 59C and the pressure receiving portion of the second control valve 56B. The fourth working oil passage 46d is an oil passage that connects the operation valve 59D and the pressure receiving portion of the second control valve 56B.

  When the first operation member 54 is tilted to the left, the operation valve 55C is operated and the pilot pressure of the pilot oil output from the operation valve 55C is set. This pilot pressure acts on the pressure receiving portion of the first control valve 56A, the boom cylinder 14 extends, and the boom 10 rises. When the first operation member 54 is tilted to the right, the operation valve 55D is operated and the pilot pressure of the pilot oil output from the operation valve 55D is set. This pilot pressure acts on the pressure receiving portion of the first control valve 56A, the boom cylinder 14 contracts, and the boom 10 descends. When the second operation member 58 is tilted to the left, the operation valve 59C is operated and the pilot pressure of the pilot oil output from the operation valve 59C is set. The pilot pressure acts on the pressure receiving portion of the second control valve 56B, the bucket cylinder 15 contracts, and the bucket 11 performs a squeeze operation. When the second operation member 58 is tilted to the right, the operation valve 59D is operated and the pilot pressure of the pilot oil output from the operation valve 59D is set. The pilot pressure acts on the pressure receiving portion of the second control valve 56B, the bucket cylinder 15 extends, and the bucket 11 performs a dumping operation.

Therefore, by moving the first operation member 58 left and right or by moving the second operation member 58 left and right, it is possible to perform work operations such as raising and lowering the boom 10, bucket dumping operation or squeezing operation.
Now, the hydraulic system is provided with a circuit capable of reducing (depressurizing) the pressure of the hydraulic oil in the traveling oil passage 45. As shown in FIG. 2, a discharge oil passage 51 for discharging hydraulic oil is connected to a travel oil passage (second oil passage) 45 that connects the travel pumps 53L and 53R, which are one of hydraulic devices, and a travel operation valve. Has been. The discharge oil passage 51 is provided with an operating valve 70A. The operation valve 70 </ b> A is a valve that can reduce the pressure of the hydraulic oil in the discharge oil passage 51, that is, a valve that can reduce the pressure of the hydraulic oil in the traveling oil passage 45 connected to the discharge oil passage 51. In other words, the operation valve 70 </ b> A is a valve that reduces the pressure (secondary pressure) of the hydraulic oil set by at least one operation valve 55 among the plurality of operation valves 55.

Hereinafter, the exhaust oil passage 51 and the operation valve 70A will be described in detail.
The drain oil passage 51 is an oil passage communicating with at least one of the travel operation valves, that is, the first operation valve 55A, the second operation valve 55B, the third operation valve 59A, and the fourth operation valve 59B. Specifically, the discharge oil passage 51 includes a first discharge oil passage 51a, a second discharge oil passage 51b, a third discharge oil passage 51c, a fourth discharge oil passage 51d, and a fifth discharge oil passage 51e. have. The 1st discharge | emission oil path 51a is an oil path branched from the middle part of the 1st driving | running | working oil path 45a. The second drain oil passage 51b is an oil passage that branches off from a midway portion of the second travel oil passage 45b. The third drain oil passage 51c is an oil passage that branches off from a midway portion of the third travel oil passage 45c. The fourth drain oil passage 51d is an oil passage that branches off from a middle portion of the fourth travel oil passage 45d. The fifth exhaust oil passage 51e is an oil passage connecting the first exhaust oil passage 51a, the second exhaust oil passage 51b, the third exhaust oil passage 51c, and the fourth exhaust oil passage 51d. An operation valve 70A is provided in the middle of the fifth discharge oil passage 51e.

In each of the first discharge oil passage 51a, the second discharge oil passage 51b, the third discharge oil passage 51c, and the fourth discharge oil passage 511d, the traveling oil passage 45 is directed to the fifth discharge oil passage 51e (the operation valve 70A). A check valve 71 is provided that allows the hydraulic oil to flow and prevents the hydraulic oil from flowing from the discharge side toward the fifth discharge oil passage 51e (operating valve 70A).
The operating valve 70A has a relief valve 78 whose set pressure can be changed. For example, the relief valve 78 is a balance type relief valve in which the set pressure varies based on the pressure of the hydraulic oil, and includes a pressure receiving portion 78a that receives the hydraulic oil. The relief valve 78 may be a variable relief valve.

When the pressure of the hydraulic oil is applied to the pressure receiving part 78a, the set pressure can be varied according to the pressure of the hydraulic oil applied to the pressure receiving part 78a. For example, the set pressure increases as the pressure of the working oil acting on the pressure receiving portion 78a increases, and the set pressure decreases as the pressure of the working oil acting on the pressure receiving portion 78a decreases.
The operating valve 70 </ b> A has a proportional valve 73 connected to the pressure receiving portion 78 a of the relief valve 78 via the oil passage 72. A discharge oil passage 40 is connected to the proportional valve 73, and hydraulic oil from the first hydraulic pump P1 can be supplied. The proportional valve 73 is an electromagnetic proportional valve whose opening degree can be changed by exciting a solenoid, and is controlled by the control device 90.

  For example, when the traveling speed of the work implement is suppressed even when the traveling operation is performed, the control device 90 outputs a control signal for exciting the solenoid of the proportional valve 73 according to the degree of suppression. Thereby, the opening degree of the proportional valve 73 is increased or decreased according to the control signal from the control device 90. When the pressure of the hydraulic oil acting on the pressure receiving portion 78a of the relief valve 78 is lowered, the set pressure of the relief valve 78 is lowered, and the hydraulic oil in the traveling oil passage 45 is discharged to the hydraulic oil tank or the like via the discharge oil passage 51. Therefore, the rotational speed of the traveling motor 36 can be reduced, and the traveling speed of the work implement can be suppressed.

  For example, when prohibiting the traveling of the work machine, the control device 90 outputs a control signal for setting the opening degree of the proportional valve 73 to the minimum. As a result, the opening degree of the proportional valve 73 is minimized, the pressure of the hydraulic oil acting on the pressure receiving part 78a of the relief valve 78 is minimized, and the set pressure of the relief valve 78 is minimized. When the set pressure of the relief valve 78 is minimized, most of the hydraulic oil in the traveling oil passage 45 is discharged to the hydraulic oil tank or the like through the discharge oil passage 51, so that the rotational speed of the traveling motor 36 becomes zero, and the working machine Is prohibited, that is, the travel can be stopped. Therefore, by making the pressure on the secondary side of the travel operation valve zero by the proportional valve 73, the work device 4 can be operated while the work implement 1 is stopped.

  In the above-described embodiment, the relief valve 78 is a valve that has a pressure receiving portion 78a that receives the hydraulic oil and reduces the set pressure by the pressure of the hydraulic oil that has acted on the pressure receiving portion 78a. An electromagnetic proportional relief valve may be used. In this case, the proportional valve 73 described above is not provided, and the control device 90 changes the set pressure of the relief valve 78 by directly outputting a control signal to the relief valve 78.

  Note that the travel hydraulic pressure (second oil passage) 45 may be provided with a check valve and a throttle portion. Specifically, a check valve 74 is provided in the first traveling oil passage 45a, the second traveling oil passage 45b, the third traveling oil passage 45d, and the fourth traveling oil passage 45e. The check valve 74 allows the hydraulic oil to flow from the operation valve side (for example, the first operation valve 55A) toward the relief valve 78 side, and allows the hydraulic oil to flow from the relief valve 78 side to the operation valve side. Stop. A bypass oil passage 75 is provided on the inlet side and the outlet side of the check valve 74, and a throttle portion 76 is provided on the bypass oil passage 75. In the traveling oil passage 45, a throttle portion 77 is provided in a section between the check valve 74 and the connection portion to which the discharge oil passage 51 is connected.

FIG. 3A shows a first modification of the hydraulic system, and FIG. 3B shows a second modification of the hydraulic system. Hereinafter, modified examples will be described.
As shown in FIG. 3A, the operation valve 70B is connected to the pilot check valve 81 capable of preventing the discharge of the hydraulic oil in the discharge oil passage 51 based on the pressure of the hydraulic oil acting on the pressure receiving portion 81a, and the oil passage 72. And a switching valve 82 connected to the pilot check valve 81. The switching valve 82 is a switching valve that can be switched between the first position 82A and the second position 82B, and is, for example, a two-position switching valve that is switched by exciting a solenoid. Based on the control signal of the control device 90, the switching valve 82 is switched to the first position 82A or the second position 82B. When the switching valve 82 is switched to the first position 82A and the pressure of the hydraulic oil applied to the pressure receiving portion 81a of the pilot check valve 81 is equal to or higher than a predetermined value, the pilot check valve 81 is closed and the hydraulic oil is discharged from the discharge oil passage 51. To prevent. Therefore, if the pilot check valve 81 prevents the discharge of the hydraulic oil in the discharge oil passage 51, the pressure of the hydraulic oil in the traveling oil passage 45 increases or decreases based on the traveling operation. Therefore, the first operating device 47 and the second operation The rotation speed of the traveling motor 36 can be changed by the device 48. On the other hand, when the switching valve 82 is switched to the second position 82B based on the control signal of the control device 90 and the pressure of the hydraulic oil applied to the pressure receiving portion 81a of the pilot check valve 81 is less than a predetermined value, the pilot check valve 81 is opened. The hydraulic oil in the discharge oil passage 51 is allowed to be discharged. Therefore, when the pilot check valve 81 allows the hydraulic oil to be discharged from the discharge oil passage 51, the hydraulic oil in the traveling oil passage 45 is discharged from the discharge oil passage 51 to the hydraulic oil tank 22 and the like. As a result, regardless of the first operating device 47 and the second operating device 48, the rotational speed of the travel motor 36 can be reduced, and the travel speed of the work implement can be suppressed or the travel of the work implement can be prohibited. it can.

  The pilot check valve 81 described above is closed when the pressure of the hydraulic oil applied to the pressure receiving portion 81a is equal to or higher than a predetermined value, and is opened when the pressure of the hydraulic oil is lower than the predetermined pressure. It may be a pilot check valve that opens when the pressure of the applied hydraulic oil is equal to or higher than a predetermined value and closes when the pressure of the hydraulic oil is lower than the predetermined pressure. In this case, the switching valve 82 switches to the first position 82A when the traveling speed of the work implement is suppressed or when traveling is prohibited.

  As shown in FIG. 3B, the operation valve 70C is switched between a first position 70C1 that allows the discharge of the hydraulic oil in the discharge oil passage 51 and a second position 70C2 that prevents the discharge of the hydraulic oil in the discharge oil passage 51. A possible switching valve, for example, a two-position switching valve that switches by exciting a solenoid. The switching valve 70C is connected to the control device 90 and switches to the first position 70C1 or the second position 70C2 based on the control signal. When the travel speed of the work implement is suppressed or the travel of the work implement is prohibited, the control device 90 switches the switching valve 70C to the first position 70C1, and when the work implement is run based on the running operation, the control valve 90C is set. Switch to the second position 70C2.

  According to the embodiment described above, all of the first traveling oil passage 45a, the second traveling oil passage 45b, the third traveling oil passage 45c, and the fourth traveling oil passage 45d are connected to the discharge oil passage 51. A drain oil passage 51 is provided in any one of the first travel oil passage 45a, the second travel oil passage 45b, the third travel oil passage 45c, and the fourth travel oil passage 45d, and the operation valves 70A, 70B, and 70C are provided in the exhaust oil passage 51. Either of these may be provided. In other words, any of the operation valves 70A, 70B, and 70C is connected to the discharge oil passage 51 that communicates with at least one of the first operation valve 55A, the second operation valve 55B, the third operation valve 59A, and the fourth operation valve 59B. It may be provided. According to this, under various circumstances, the operation of the hydraulic system of the traveling system can be suppressed or prohibited. For example, the working machine travels forward, backward, right turn, left turn, left turn, right turn, etc. Can be suppressed (restricted).

  Further, the working oil passage 46 may be the second oil passage, the discharge oil passage 51 may be provided in the working oil passage (second oil passage) 46, and any of the operation valves 70A, 70B, and 70C may be provided in the discharge oil passage 51. Good. In other words, the operation valve 55C is the first operation valve, the operation valve 55D is the second operation valve, the operation valve 59C is the third operation valve, and the operation valve 59D is the fourth operation valve. Any of the operation valves 70A, 70B, and 70C may be provided in the discharge oil passage 51 that communicates with at least one of the valve 55D, the third operation valve 59C, and the fourth operation valve 59D. According to this, under various circumstances, the operation of the working hydraulic device can be suppressed or prohibited.

Further, the oil discharge passage 51 may be provided in both the traveling oil passage 45 and the working oil passage 46, and any one of the operation valves 70A, 70B, and 70C may be provided in the discharge oil passage 51. In the case where the discharge oil passage 51 is provided in the second oil passage (travel oil passage 45, work oil passage 46), a check valve 74, a bypass oil passage 75, and throttle portions 76, 77 may be provided.
Further, the operation valve may be any valve that controls the discharge of the operation oil in the discharge oil passage 51, and is not limited to the operation valves 70A, 70B, and 70C described above.

Further, a check valve for setting the differential pressure may be provided in the downstream oil passage connected to the discharge oil passage 51 or the pressure receiving portion 70a. The spring strength of the check valve 71 is set separately for each of the first exhaust oil passage 51a, the second exhaust oil passage 51b, the third exhaust oil passage 51c, the fourth exhaust oil passage 51d, and the fifth exhaust oil passage 51e. May be.
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

1 working machine 45 traveling oil passage (second oil passage)
46 Working oil passage (second oil passage)
51 Oil discharge passage 54 First operation member 55, 55A, 55B, 55C, 55D Operation valve 58 Second operation member 59, 59A, 59B, 59C, 59D Operation valve 70A, 70B, 70C Actuation valve 70a Pressure receiving portion 71 Check valve 72 oil passage 73 switching valve 74 check valve 75 bypass oil passage 76 throttling portion 77 throttling portion 78 relief valve 78a pressure receiving portion 81 pilot check valve 81a pressure receiving portion 82 switching valve 82A first position 82B second position

Claims (9)

A hydraulic pump that discharges hydraulic oil;
Hydraulic equipment operable by hydraulic oil,
An operating member for operating the hydraulic device;
A plurality of operation valves capable of changing the pressure of the hydraulic oil according to the operation of the operation member;
A discharge oil passage communicating with at least one of the plurality of operation valves and discharging hydraulic oil;
An operating valve provided in the exhaust oil passage and capable of reducing the pressure of the operating oil in the exhaust oil passage;
The working machine's hydraulic system. A hydraulic pump that discharges hydraulic oil;
Hydraulic equipment operable by hydraulic oil,
A first operating member operable in one direction and the other direction, a first operating valve capable of changing the pressure of hydraulic oil in accordance with an operation in one direction of the first operating member, and an operation in the other direction of the first operating member A first operating device that has a second operating valve that can change the pressure of the hydraulic oil according to the operation of the hydraulic device;
An operating device different from the first operating device, wherein a second operating member that can be operated in one direction and the other direction, and a hydraulic oil pressure that can be changed according to an operation in one direction of the second operating member. A third operating valve, a second operating device having a fourth operating valve capable of changing the pressure of the hydraulic oil according to an operation in the other direction of the second operating member, and operating the hydraulic device;
A discharge oil passage that communicates with at least one of the first operation valve, the second operation valve, the third operation valve, and the fourth operation valve and discharges hydraulic oil;
An operating valve provided in the exhaust oil passage and capable of reducing the pressure of the operating oil in the exhaust oil passage;
The working machine's hydraulic system.   The working machine hydraulic system according to claim 1, wherein the operating valve includes a relief valve whose set pressure can be changed.   The operation valve according to claim 3, wherein the operation valve includes a proportional valve that is connected to a pressure receiving portion of the relief valve and can change the set pressure by changing a pressure of hydraulic oil that acts on the pressure receiving portion. Machine hydraulic system. A second oil passage that connects the plurality of operation valves and the hydraulic device, and the drain oil passage is connected;
Check that is provided in the discharge oil passage and allows the operation oil to flow from the second oil passage toward the operation valve and prevents the operation oil from flowing from the discharge side toward the second oil passage. The hydraulic system for a working machine according to claim 1, further comprising a valve. A second oil passage connecting the first operation valve, the second operation valve, the third operation valve and the fourth operation valve and the hydraulic device, and the exhaust oil passage being connected;
Check that is provided in the discharge oil passage and allows the operation oil to flow from the second oil passage toward the operation valve and prevents the operation oil from flowing from the discharge side toward the second oil passage. The working system hydraulic system according to claim 2, further comprising a valve.   The said operation valve has a pilot check valve which can prevent discharge | emission of the hydraulic oil in the said discharge oil path based on the pressure of the hydraulic oil which acted on the pressure receiving part. The hydraulic system of the working machine described in Crab.   The operation valve has a switching valve that can be switched between a first position that allows the discharge of the hydraulic oil in the discharge oil passage and a second position that prevents the discharge of the hydraulic oil in the discharge oil passage. Item 7. The working machine hydraulic system according to any one of Items 1, 2, 5, and 6.   The hydraulic system for a working machine according to any one of claims 1 to 8, wherein the hydraulic device is a traveling pump whose output changes depending on the pressure of hydraulic oil.

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