The present application claims priority under 35 U. S. C. §119 to Japanese Patent Application No. 2020-171755, filed Oct. 12, 2020. The contents of this application are incorporated herein by reference in their entirety.
The present invention relates to a work vehicle.
Japanese Patent Application Laid-Open No. 2020-012350 describes a hydraulic circuit that controls two hydraulic motors for traveling, which are disposed on left and right side surfaces of a work vehicle.
According to a first aspect of the present disclosure, a work vehicle includes a vehicle body, a first travel device, a second travel device, a first hydraulic motor, a second hydraulic motor, a first hydraulic pump, a second hydraulic pump, an operation device, a first pilot oil passage, a second pilot oil passage, a third pilot oil passage, a fourth pilot oil passage, a first bypass oil passage, a second bypass oil passage, a first throttle, and a second throttle. The vehicle body has a first side surface and a second side surface opposite to the first side surface. The first travel device is provided on the first side surface of the vehicle body. The second travel device is provided on the second side surface of the vehicle body. The first hydraulic motor is configured to drive the first travel device. The second hydraulic motor is configured to drive the second travel device. The first hydraulic pump is connected to the first hydraulic motor via a first hydraulic circuit. The first hydraulic pump has a first port and a second port. When the hydraulic pressure applied to the first port is higher than the hydraulic pressure applied to the second port, the first hydraulic pump supplies hydraulic oil to the first hydraulic motor via the first hydraulic circuit so as to drive the first travel device forward. The first hydraulic pump is configured to supply hydraulic oil to the first hydraulic motor via the first hydraulic circuit so as to drive the first travel device to move backward when the hydraulic pressure applied to the second port is higher than the hydraulic pressure applied to the first port. The second hydraulic pump is connected to the second hydraulic motor via a second hydraulic circuit. The second hydraulic pump has a third port and a fourth port. When the hydraulic pressure applied to the third port is higher than the hydraulic pressure applied to the fourth port, the second hydraulic pump supplies hydraulic oil to the second hydraulic motor via the second hydraulic circuit so as to drive the second travel device forward. The second hydraulic pump is configured to supply hydraulic oil to the second hydraulic motor via the second hydraulic circuit so as to drive the second travel device to move backward when the hydraulic pressure applied to the fourth port is higher than the hydraulic pressure applied to the third port. The operation device is configured to select at least one travel device out of the first travel device and the second travel device and to operate forward or backward movement of the at least one travel device. The first pilot oil passage connects the operation device and the first port. The second pilot oil passage connects the operation device and the second port. The third pilot oil passage connects the operation device and the third port. The fourth pilot oil passage connects the operation device and the fourth port. The first bypass oil passage connects the first pilot oil passage and the fourth pilot oil passage. The second bypass oil passage connects the second pilot oil passage and the third pilot oil passage. The first throttle is provided in the first bypass oil passage. The second throttle is provided in the second bypass oil passage. The first, second, third, and fourth pilot oil passages pass through an identical connector.
Hereinafter, the present invention will be described in detail with reference to the drawings showing embodiments thereof. In the drawings, the same reference numerals denote corresponding or substantially identical components.
Referring to
The link 44 is rotatable relative to the vehicle body 2 about a fulcrum shaft 46. The arm 45 is rotatable relative to the link 44 about a joint shaft 47. The work device 4 further includes a plurality of arm cylinders 48 and at least one equipment cylinder 49. Each of the plurality of arm cylinders 48 is rotatably connected to the vehicle body 2 and the arm 45, and moves the link 44, the arm 45, and the like to raise and lower the bucket 41. The at least one implement cylinder 49 is configured to tilt the bucket 41. The vehicle body 2 includes a cabin 5. The cabin 5 includes a front window 51 that can be opened and closed, and is defined by a cab frame 53. The front window 51 may be omitted. The work vehicle 1 includes an operator's seat 54 and an operation lever 55 in a cabin 5. The cab frame 53 is rotatable about rotational shafts RSL and RSR on the vehicle body 2, as shown in
In the embodiment according to the present application, the front-rear direction DFB (front direction DF /rear direction DB) means a front-rear direction (front direction/rear direction) as viewed from an operator seated in the operator's seat 54 of the cabin 5. The left direction DL, the right direction DR, and the width direction DW respectively mean a left direction, a right direction, and a left and right direction as viewed from the operator. The upward direction DU, the downward direction DD, and the height direction DH mean an upward direction, a downward direction, and a height direction as viewed from the operator. The front-rear/left-right (width)/up-down (height) directions of the work vehicle 1 respectively coincide with the front-rear/left-right (width)/up-down (height) directions viewed from the operator.
Referring to
The hydraulic circuit 1A includes a pilot oil supply passage PA1 connected to a discharge port of the first hydraulic pump P1. The pilot oil flows through the pilot oil supply passage PA1. The hydraulic circuit 1A includes a plurality of switching valves (a brake switching valve SV1, a direction switching valve SV2, and a hydraulic lock switching valve SV3) connected to the pilot oil supply passage PA1, and a plurality of brake mechanisms 72. The brake switching valve SV1 is connected to the pilot oil supply passage PA1. The brake switching valve SV1 is a direction switching valve (electromagnetic valve) to brake and release braking by the plurality of brake mechanisms 72. The brake switching valve SV1 is a two position switching valve configured to switch a valve body thereof to a first position VP1a or a second position VP1b by excitation. Switching of the valve body of the brake switching valve SV1 is performed by an operation member (not illustrated) or the like.
The plurality of brake mechanisms 72 include a first brake mechanism 72L to brake the first travel device 3L and a second brake mechanism 72R to brake the second travel device 3R. The first brake mechanism 72L and the second brake mechanism 72R are connected to the brake switching valve SV1 via an oil passage PA2. The first brake mechanism 72L and the second brake mechanism 72R are configured to brake the travel devices 3 in accordance with the pressure of the pilot oil (hydraulic fluid). When the valve body of the brake switching valve SV1 is switched to the first position VP1a, the hydraulic oil is drained from the oil passage PA2 in the section between the brake switching valve SV1 and the brake mechanisms 72, and the travel devices 3 are braked by the brake mechanisms 72. When the valve body of the brake switching valve SV1 is switched to the second position VP1b, braking by the brake mechanisms 72 is released. Alternatively, when the valve body of the brake switching valve SV1 is switched to the first position VP1a, the braking by the brake mechanisms 72 may be released, and when the valve body of the brake switching valve SV1 is switched to the second position VP1b, the travel devices 3 may be braked by the brake mechanisms 72.
The direction switching valve SV2 is an electromagnetic valve to change the rotation of the first hydraulic motor device 30L and the second hydraulic motor device 30R. The direction switching valve SV2 is a two position switching valve configured to switch a valve body thereof to a first position VP2a or a second position VP2b by excitation. The directional control valve SV2 is switched by an operating member (not illustrated) or the like. The direction switching valve SV2 may be a proportional valve capable of adjusting the flow rate of the hydraulic fluid to be discharged, instead of the two position switching valve.
The first hydraulic motor device 30L is a device to transmit power to the drive wheel 31 provided in the first travel device 3L. The first hydraulic motor device 30L includes a first hydraulic motor 31L, a first swash plate switching cylinder 32L, and a first travel control valve (hydraulic switching valve) SV4. The first hydraulic motor 31L is a swash plate type variable displacement axial motor to drive the first travel device 3L, and is a motor capable of changing the vehicle speed (rotation) to first speed or second speed. The first swash plate switching cylinder 32L is a cylinder configured to change the angle of the swash plate of the first hydraulic motor 31L by expansion and contraction. The first travel control valve SV4 is a valve to expand and contract the first swash plate switching cylinder 32L. The first travel control valve SV4 is a two position switching valve configured to switch a valve body thereof to a first position VP4a or a second position VP4b.
The first travel control valve SV4 is switched by a directional control valve SV2 located on the upstream side connected to the first travel control valve SV4. Specifically, the direction switching valve SV2 and the first travel control valve SV4 are connected by an oil passage PA3, and the first travel control valve SV4 is switched by the hydraulic oil flowing through the oil passage PA3. For example, when the valve body of the direction switching valve SV2 is switched to the first position VP2a by the operation of the operation member, the pilot oil is released in the section between the direction switching valve SV2 and the first travel control valve SV4, and the valve body of the first travel control valve SV4 is switched to the first position VP4a. As a result, the first swash plate switching cylinder 32L contracts, and the speed of the first hydraulic motor 31L is changed to the first speed. When the valve body of the direction switching valve SV2 is switched to the second position VP2b by the operation of the operation member, the pilot oil is supplied to the first travel control valve SV4 through the direction switching valve SV2, and the valve body of the first travel control valve SV4 is switched to the second position VP4b. As a result, the first swash plate switching cylinder 32L extends, and the speed of the first hydraulic motor 31L is changed to the second speed.
The second hydraulic motor device 30R is a device to transmit power to the drive wheel 31 provided in the second travel device 3R. The second hydraulic motor device 30R includes a second hydraulic motor 31R, a second swash plate switching cylinder 32R, and a second travel control valve (hydraulic switching valve) SV5. The second hydraulic motor device 30R is a hydraulic motor to drive the second travel device 3R, and operates in the same manner as the first hydraulic motor device 30L. That is, the second hydraulic motor 31R operates in the same manner as the first hydraulic motor 31L. The second swash plate switching cylinder 32R operates in the same manner as the first swash plate switching cylinder 32L. The second travel control valve SV5 is a two position switching valve configured to switch a valve body thereof to a first position VP5a or a second position VP5b, and operates in the same manner as the first travel control valve SV4.
A drain oil passage DR1 is connected to the hydraulic circuit 1A. The drain oil passage DR1 is an oil passage through which the pilot oil flows from the plurality of switching valves (the brake switching valve SV1, the direction switching valve SV2, and the hydraulic lock switching valve SV3) to the hydraulic fluid tank 70. For example, the drain oil passage DR1 is connected to discharge ports of a plurality of switching valves (the brake switching valve SV1, the direction switching valve SV2, and the hydraulic lock switching valve SV3). That is, when the brake switching valve SV1 is in the first position VP1a, the hydraulic oil is discharged from the oil passage PA2 to the drain oil passage DR1 in the section between the brake switching valve SV1 and the brake mechanisms 72. When the direction switching valve SV2 is at the first position VP1a, the pilot oil in the oil passage PA3 is discharged to the drain oil passage DR1.
The hydraulic circuit 1A further includes a first charge oil passage PA4 and a hydraulic drive device 75. The first charge oil passage PA4 is branched from the pilot oil supply passage PA1 and connected to the hydraulic drive device 75. The hydraulic drive device 75 is a device to drive the first hydraulic motor device 30L and the second hydraulic motor device 30R. The hydraulic drive device 75 includes a first drive circuit 76L for driving the first hydraulic motor device 30L and a second drive circuit 76R for driving the second hydraulic motor device 30R.
The first drive circuit 76L includes a first hydraulic pump 7L, drive oil passages PA5L and PA6L, and a second charge oil passage PA7L. The driving oil passages PA5L and PA6L connect the first hydraulic pump 7L and the first hydraulic motor 31L. A hydraulic circuit formed by the driving oil passages PA5L and PA6L is referred to as a first hydraulic circuit CL. The second charge oil passage PA7L is an oil passage that is connected to the driving oil passages PA5L and PA6L and replenishes the driving oil passages PA5L and PA6L with the hydraulic oil from the third hydraulic pump 71.
Similarly, the second drive circuit 76R includes a second hydraulic pump 7R, drive oil passages PA5R and PA6R, and a third charge oil passage PA7R. The driving oil passages PA5R and PA6R connect the second hydraulic pump 7R and the second hydraulic motor 31R. A hydraulic circuit formed by the drive oil passages PA5R and PA6R is referred to as a second hydraulic circuit CR. The third charge oil passage PA7R is an oil passage that is connected to the driving oil passages PA5R and PA6R and replenishes the driving oil passages PA5R and PA6R with the hydraulic oil from the third hydraulic pump 71.
The first hydraulic pump 7L and the second hydraulic pump 7R are swash plate type variable displacement axial pumps to be driven by the power of the engine 6. The first hydraulic pump 7L is connected to the first hydraulic motor 31L via the first hydraulic circuit CL, and has a first port PLa and a second port PLb on which the pilot pressure acts. In the first hydraulic pump 7L, the angle of the swash plate is changed by the pilot pressure acting on the first port PLa and the second port PLb. Specifically, the first hydraulic pump 7L is configured to supply hydraulic fluid to the first hydraulic motor 31L via the first hydraulic circuit CL to drive the first travel device 3L forward when the hydraulic pressure applied to the first port PLa is higher than the hydraulic pressure applied to the second port PLb, and to supply hydraulic fluid to the first hydraulic motor 31L via the first hydraulic circuit CL to drive the first travel device 3L backward when the hydraulic pressure applied to the second port PLb is higher than the hydraulic pressure applied to the first port PLa.
The second hydraulic pump 7R is connected to the second hydraulic motor 31R via the second hydraulic circuit CR, and has a third port PRa and a fourth port PRb on which the pilot pressure acts. In the second hydraulic pump 7R, the angle of the swash plate is changed by the pilot pressure acting on the third port PRa and the fourth port PRb. Specifically, the second hydraulic pump 7R is configured to supply hydraulic fluid to the second hydraulic motor 31R via the second hydraulic circuit CR to drive the second travel device 3R forward when the hydraulic pressure applied to the third port PRa is higher than the hydraulic pressure applied to the fourth port PRb, and to supply hydraulic fluid to the second hydraulic motor 31R via the second hydraulic circuit CR to drive the second travel device 3R backward when the hydraulic pressure applied to the fourth port PRb is higher than the hydraulic pressure applied to the third port PRa. The first hydraulic pump 7L and the second hydraulic pump 7R can change the output (the discharge amount of the hydraulic oil) and the discharge direction of the hydraulic oil according to the angle of the swash plate.
The outputs of the first hydraulic pump 7L and the second hydraulic pump 7R and the discharge direction of the hydraulic oil are changed by the operation device 56. Specifically, the outputs of the first hydraulic pump 7L and the second hydraulic pump 7R and the discharge direction of the hydraulic oil are changed according to the operation of the operation lever 55 included in the operation device 56. That is, the operation device 56 is a device to select at least one travel device out of the first travel device 3L and the second travel device 3R and to operate forward or backward movement of the at least one travel device.
As shown in
The hydraulic lock switching valve SV3 is a two position switching valve configured to switch a valve body thereof to a first position VP3a or a second position VP3b. The switching of the valve body of the hydraulic lock switching valve SV3 is performed by an operation member (not shown) or the like. When the valve body of the hydraulic lock switching valve SV3 is switched to the first position VP3a, the hydraulic oil (pilot oil) in the oil passage PA9 is discharged to the hydraulic fluid tank 70. The oil passage PA9 is also connected to an oil passage PA10 that is connected to an operation device for controlling the work device 4 (not shown), and the pilot oil in the oil passage PA9 is discharged to the hydraulic fluid tank 70, whereby the pilot oil is not supplied to the operation device for controlling the work device 4. Further, even when it is not necessary to supply the operating oil (pilot oil) to the operation device 56, for example, when the work vehicle 1 is stopped, the warm-up can be performed by flowing the operating oil through the oil passage PA8, the throttle check valve TC1, the oil passage PA9, and the drain oil passage DR1. Therefore, the oil passage PA8 and the oil passage PA9 are also referred to as warm-up oil passages. When the valve body of the hydraulic lock switching valve SV3 is switched to the second position VP3b, the pilot oil in the pilot oil supply passage PA1 is supplied to the oil passage PA10. Thus, the pilot oil is supplied to the operation device for controlling the work device 4.
The operation device 56 includes an operating valve OVA for forward travel, an operating valve OVB for rearward travel, an operating valve OVC for right turn, an operating valve OVD for left turn, and an operation lever 55. The operation device 56 includes first to fourth shuttle valves SVa, SVb, SVc, and SVd. The operating valves OVA, OVB, OVC, and OVD are operated by a single operation lever 55. The operating valves OVA, OVB, OVC, and OVD change the pressure of the hydraulic fluid according to the operation of the operation lever 55, and supply the changed hydraulic fluid to the first port PLa and the second port PLb of the first hydraulic pump 7L and the third port PRa and the fourth port PRb of the second hydraulic pump 7R. In this embodiment, the operating valves OVA, OVB, OVC, and OVD are operated by the single operation lever 55, but a plurality of operation levers 55 may be provided.
The operating valves OVA, OVB, OVC, and OVD have discharge ports (ports). As shown in
The operating valves OVA, OVB, OVC, and OVD of the operation device 56 are operated in accordance with the tilting of the operation lever 55. Thus, the pilot pressure proportional to the operation amount of the operation lever 55 from the neutral position is output from the second side ports of the operating valves OVA, OVB, OVC, and OVD.
When the operation lever 55 is tilted forward, the operating valve OVA for forward travel is operated, and the pilot pressure is output from the operating valve OVA. The pilot pressure acts on the first port PLa from the first shuttle valve SVa via a first pilot oil passage PA11 connecting the operation device 56 and the first port PLa of the first hydraulic pump 7L, and acts on the third port PRa from the second shuttle valve SVb via a third pilot oil passage PA13 connecting the operation device 56 and the third port PRa of the second hydraulic pump 7R. As a result, the output shaft of the first hydraulic pump 7L and the output shaft of the second hydraulic pump 7R rotate forward (forward rotation) at a speed proportional to the amount of tilt of the operation lever 55, and the work vehicle 1 moves straight forward.
When the operation lever 55 is tilted rearward, the operating valve OVB for rearward travel is operated to output a pilot pressure. The pilot pressure acts on the second port PLb of the first hydraulic pump 7L from the third shuttle valve SVc via a second pilot oil passage PA12 connecting the operation device 56 and the second port, and acts on the fourth port PRb from the fourth shuttle valve SVd via a fourth pilot oil passage PA14 connecting the operation device 56 and the fourth port PRb of the second hydraulic pump 7R. As a result, the output shaft of the first hydraulic pump 7L and the output shaft of the second hydraulic pump 7R rotate in reverse (reverse rotation) at a speed proportional to the amount of tilting of the operation lever 55, and the work vehicle 1 moves straight rearward.
When the operation lever 55 is tilted to the right, the operating valve OVC for turning to the right is operated, and the pilot pressure is output from the operating valve OVC. This pilot pressure acts on the first port PLa of the first hydraulic pump 7L from the first shuttle valve SVa via the first pilot oil passage PA11, and also acts on the fourth port PRb of the second hydraulic pump 7R from the fourth shuttle valve SVd via the fourth pilot oil passage PA14. As a result, the output shaft of the first hydraulic pump 7L rotates in the forward direction and the output shaft of the second hydraulic pump 7R rotates in the reverse direction, so that the work vehicle 1 turns to the right.
Further, when the operation lever 55 is tilted to the left, the operating valve OVD for turning to the left is operated, and the pilot pressure is output from the operating valve OVD. This pilot pressure acts on the third port PRa of the second hydraulic pump 7R from the second shuttle valve SVb via the third pilot oil passage PA13, and also acts on the second port PLb of the first hydraulic pump 7L from the third shuttle valve SVc via the second pilot oil passage PA12. Thus, the output shaft of the second hydraulic pump 7R rotates in the forward direction and the output shaft of the first hydraulic pump 7L rotates in the reverse direction, so that the work vehicle 1 turns to the left.
That is, when the operation lever 55 is tilted diagonally forward to the left, the work vehicle 1 turns to the left while moving forward at a speed corresponding to the tilt angle of the operation lever 55. When the operation lever 55 is tilted obliquely forward to the right, the work vehicle 1 turns to the right while moving forward at a speed corresponding to the tilt angle of the operation lever 55. When the operation lever 55 is tilted diagonally backward to the left, the work vehicle 1 turns left while moving backward at a speed corresponding to the tilt angle of the operation lever 55. When the operation lever 55 is tilted obliquely backward to the right, the work vehicle 1 turns to the right while moving backward at a speed corresponding to the tilt angle of the operation lever 55.
The hydraulic circuit 1A further includes a first bypass oil passage B1, a second bypass oil passage B2, a third bypass oil passage B3, a fourth bypass oil passage B4, a fifth bypass oil passage B5, and a sixth bypass oil passage B6. The first bypass oil passage B1 connects the first pilot oil passage PA11 and the fourth pilot oil passage PA14. The second bypass oil passage B2 connects the second pilot oil passage PA12 and the third pilot oil passage PA13. The third bypass oil passage B3 connects the first pilot oil passage PA11 and the drain oil passage DR2. The fourth bypass oil passage B4 connects the second pilot oil passage PA12 and the drain oil passage DR2. The fifth bypass oil passage B5 connects the third pilot oil passage PA13 and the drain oil passage DR2. The sixth bypass oil passage B6 connects the fourth pilot oil passage PA14 and the drain oil passage DR2.
The hydraulic circuit 1A further includes a first throttle TH1, a second throttle TH2, a third throttle TH3, a fourth throttle TH4, a fifth throttle TH5, and a sixth throttle TH6. The first throttle TH1 is provided in the first bypass oil passage B1. The second throttle TH2 is provided in the second bypass oil passage B2. The third throttle TH3 is provided in the third bypass oil passage B3. The fourth throttle TH4 is provided in the fourth bypass oil passage B4. The fifth throttle TH5 is provided in the fifth bypass oil passage B5. The sixth throttle TH6 is provided in the sixth bypass oil passage B6. The first bypass oil passage B1 to the sixth bypass oil passage B6 and the first throttle TH1 to the sixth throttle TH6 are formed by the connector (relay member) 10 that is integrally molded. That is, the first bypass oil passage B1 to the sixth bypass oil passage B6 and the first throttle TH1 to the sixth throttle TH6 are provided inside the connector 10. The first pilot oil passage PA11, the second pilot oil passage PA12, the third pilot oil passage PA13, and the fourth pilot oil passage PA14 pass through an identical connector 10.
The first bypass oil passage B1 and the first throttle TH1 allow oil to escape from the first pilot oil passage PA11 to the fourth pilot oil passage PA14 when a right pivot turn is to be performed from the forward movement. Therefore, the pilot pressure of the fourth port PRb is increased. In a case where the first bypass oil passage B1 and the first throttle TH1 are not provided, the differential pressure between the pilot pressure of the third port PRa and the pilot pressure of the fourth port PRb increases as the tilting amount of the operation lever 55 for forward movement increases when the vehicle turns from forward movement to the right pivot turn, even if the operation lever 55 is subsequently tilted to the right by the same degree. Therefore, in order to shift to the right pivot turn, it is necessary to tilt the operation lever 55 further to the right. Therefore, the operation of the operation lever 55 for changing from the forward movement to the right pivot turn differs depending on the tilting operation of the operation lever 55 of the immediately preceding forward movement, thereby reducing the operability. On the other hand, when the first bypass oil passage B1 and the first throttle TH1 are provided, the pilot pressure of the fourth port PRb increases as the forward lever operation increases. Therefore, even if the operation lever 55 is thereafter tilted to the right by the same degree, the differential pressure between the pilot pressure of the third port PRa and the pilot pressure of the fourth port PRb is smaller than that in the case where the first bypass oil passage B1 and the first throttle TH1 are not provided. Therefore, when the right pivot turn is to be performed from the forward movement, even if the lever operation of the immediately preceding forward movement is different, the right pivot turn can be performed by a similar tilting operation to the right side. Therefore, the operability of shifting from the forward movement to the right pivot turn is improved.
Further, since the first bypass oil passage B1 and the first throttle TH1 allow the oil to escape from the fourth pilot oil passage PA14 to the first pilot oil passage PA11 when the forward movement is to be performed from the right pivot turn while moving forward, the differential pressure between the pilot pressure of the third port PRa and the pilot pressure of the fourth port PRb becomes larger than that in the case where the first bypass oil passage B1 and the first throttle TH1 are not provided. Therefore, when the forward movement is to be performed from the right pivot turn while moving forward, even if the lever operation of the immediately preceding right pivot turn is different, the forward movement can be performed by a similar forward tilting operation. Therefore, the operability of shifting from the right pivot turn while moving forward to the forward movement is improved.
Further, since the second bypass oil passage B2 and the second throttle TH2 allow the oil to escape from the second pilot oil passage PA12 to the third pilot oil passage PA13 when the right pivot turn is to be performed the from the backward movement, the differential pressure between the pilot pressure of the third port PRa and the pilot pressure of the fourth port PRb becomes smaller than that in the case where the second bypass oil passage B2 and the second throttle TH2 are not provided. Therefore, when the right pivot turn is to be performed from the backward movement, the right pivot turn can be performed by a similar rightward tilting operation even if the lever operation of the immediately preceding backward movement is different. Therefore, the operability of shifting from the backward movement to the right pivot turn is improved.
In addition, even in a case where the backward movement is to be performed from the right pivot turn while moving backward, the second bypass oil passage B2 and the second throttle TH2 allow the oil to escape from the third pilot oil passage PA13 to the second pilot oil passage PA12. Thus, the differential pressure between the pilot pressure of the third port PRa and the pilot pressure of the fourth port PRb is larger than that in the case where the second bypass oil passage B2 and the second throttle TH2 are not provided. Therefore, when the backward movement is to be performed from the right pivot turn while moving backward, even if the lever operation of the immediately preceding right pivot turn is different, the backward movement can be performed by a similar rearward tilting operation. Therefore, the operability of shifting from the right pivot turn while moving backward to the backward movement is improved.
Similarly, the second bypass oil passage B2 and the second throttle TH2 allow the oil to escape from the third pilot oil passage PA13 to the second pilot oil passage PA12 when a left pivot turn is performed from forward movement. Therefore, the pilot pressure of the second port PLb is increased. In a case where the second bypass oil passage B2 and the second throttle TH2 are not provided, the differential pressure between the pilot pressure of the first port PLa and the pilot pressure of the second port PLb increases as the tilting of the operation lever 55 for the forward movement increases when the left pivot turn is performed from the forward movement even if the operation lever 55 is tilted to the left by the same degree. Therefore, in order to shift to the left pivot turn, it is necessary to tilt the operation lever 55 further to the left. Therefore, the operation of the operation lever 55 for changing from the forward movement to the left pivot turn differs depending on the tilting operation of the operation lever 55 of the immediately preceding forward movement, thereby reducing the operability. On the other hand, when the second bypass oil passage B2 and the second throttle TH2 are provided, the pilot pressure of the second port PLb increases as the forward lever operation increases. Therefore, even if the operation lever 55 is thereafter tilted to the left by the same degree, the differential pressure between the pilot pressure of the first port PLa and the pilot pressure of the second port PLb becomes smaller than that in the case where the second bypass oil passage B2 and the second throttle TH2 are not provided. Therefore, when the left pivot turn is to be performed from the forward movement, even if the lever operation of the immediately preceding forward movement is different, the left pivot turn can be performed by a similar tilting operation to the left. Therefore, the operability of shifting from the forward movement to the left pivot turn is improved.
Further, since the second bypass oil passage B2 and the second throttle TH2 allow the oil to escape from the second pilot oil passage PA12 to the third pilot oil passage PA13 when the forward movement is to be performed from the left pivot turn while moving forward, the differential pressure between the pilot pressure of the first port PLa and the pilot pressure of the second port PLb becomes larger than that in the case where the second bypass oil passage B2 and the second throttle TH2 are not provided. Therefore, when the forward movement is to be performed from the left pivot turn while moving forward, the forward movement can be performed by a similar forward tilting operation even if the lever operation of the immediately preceding left pivot turn is different. Therefore, the operability of shifting from the left pivot turn while moving forward to the forward movement is improved.
Further, since the first bypass oil passage B1 and the first throttle TH1 allow the oil to escape from the fourth pilot oil passage PA14 to the first pilot oil passage PA11 when the left pivot turn is to be performed from the backward movement, the differential pressure between the pilot pressure of the first port PLa and the pilot pressure of the second port PLb becomes smaller than that in the case where the first bypass oil passage B1 and the first throttle TH1 are not provided. Therefore, when the left pivot turn is to be performed from the backward movement, even if the lever operation of the immediately preceding backward movement is different, the left pivot turn can be performed by a similar tilting operation to the left. Therefore, the operability of shifting from the backward movement to left pivot turn is improved.
In addition, even in a case where the backward movement is to be performed from the left pivot turn while moving backward, the first bypass oil passage B1 and the first throttle TH1 allow the oil to escape from the first pilot oil passage PA11 to the fourth pilot oil passage PA14. Thus, the differential pressure between the pilot pressure of the first port PLa and the pilot pressure of the second port PLb is larger than that in a case where the first bypass oil passage B1 and the first throttle TH1 are not provided. Therefore, when the backward movement is to be performed from the left pivot turn while moving backward, even if the lever operation of the immediately preceding left pivot turn is different, the backward movement can be performed by a similar rearward tilting operation. Therefore, the operability of shifting from the left pivot turn while moving backward to the backward movement is improved.
Since the pilot pressure of the first pilot oil passage PA11 is higher than the hydraulic pressure of the drain oil passage DR2, the air accumulated in the first pilot oil passage PA11 is easily discharged to the drain oil passage DR2 via the third bypass oil passage B3 and the third throttle TH3. Similarly, since the pilot pressure of the second pilot oil passage PA12 is higher than the hydraulic pressure of the drain oil passage DR2, the air accumulated in the second pilot oil passage PA12 is easily discharged to the drain oil passage DR2 via the fourth bypass oil passage B4 and the fourth throttle TH4. Since the pilot pressure of the third pilot oil passage PA13 is higher than the hydraulic pressure of the drain oil passage DR2, the air accumulated in the third pilot oil passage PA13 is easily discharged to the drain oil passage DR2 via the fifth bypass oil passage B5 and the fifth throttle TH5. Since the pilot pressure of the fourth pilot oil passage PA14 is higher than the hydraulic pressure of the drain oil passage DR2, the air accumulated in the fourth pilot oil passage PA14 is easily discharged to the drain oil passage DR2 via the sixth bypass oil passage B6 and the sixth throttle TH6. Since the drain oil passage DR2 includes an air vent hole AV (see
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In the present embodiment, the work vehicle 1 includes a vehicle body 2, a first travel device 3L, a second travel device 3R, a first hydraulic motor 31L, a second hydraulic motor 31R, a first hydraulic pump 7L, a second hydraulic pump 7R, and an operation device 56. The work vehicle 1 further includes a first pilot oil passage PA11, a second pilot oil passage PA12, a third pilot oil passage PA13, a fourth pilot oil passage PA14, a first bypass oil passage B1, a second bypass oil passage B2, a first throttle TH1, and a second throttle TH2. The first pilot oil passage PA11 connects the operation device 56 and the first port PLa of the first hydraulic pump 7L. The second pilot oil passage PA12 connects the operation device 56 and the second port PLb of the first hydraulic pump 7L. The third pilot oil passage PA13 connects the operation device 56 and the third port PRa of the second hydraulic pump 7R. The fourth pilot oil passage PA14 connects the operation device 56 and the fourth port PRb of the second hydraulic pump 7R. The first bypass oil passage B1 connects the first pilot oil passage PA11 and the fourth pilot oil passage PA14. The second bypass oil passage B2 connects the second pilot oil passage PA12 and the third pilot oil passage PA13. The first throttle TH1 is provided in the first bypass oil passage B1. The second throttle TH2 is provided in the second bypass oil passage B2.
The first bypass oil passage B1 and the first throttle TH1 allow the oil to escape from the first pilot oil passage PA11 to the fourth pilot oil passage PA14 when the right pivot turn is to be performed from forward movement. Therefore, the pilot pressure of the fourth port PRb of the second hydraulic pump 7R is increased, so that the operability of shifting to the right pivot turn is improved. The second bypass oil passage B2 and the second throttle TH2 allow the oil to escape from the third pilot oil passage PA13 to the first pilot oil passage PA11 when the left pivot turn is to be performed from forward movement. Therefore, the pilot pressure of the second port PLb of the first hydraulic pump 7L is increased, so that the operability of shifting to the left pivot turn is improved.
In the above-described embodiment, the channels forming the first pilot oil passage PA11 in the connector 10 and the channels forming the fourth pilot oil passage PA14 in the connector 10 may be switched, and the channel forming the second pilot oil passage PA12 in the connector 10 and the channel forming the third pilot oil passage PA13 in the connector 10 may be switched. Further, the combination of the channel forming the first pilot oil passage PA11 in the connector 10 and the channel forming the fourth pilot oil passage PA14 in the connector 10 may be replaced with the combination of the channels forming the second pilot oil passage PA12 in the connector 10 and the channel forming the third pilot oil passage PA13 in the connector 10.
In this application, “comprising” and its derivatives are open-ended terms that describe the presence of elements and do not exclude the presence of other elements not described. This also applies to “having”, “including” and derivatives thereof.
The terms “ . . . member”, “. . . part”, “ . . . element”, “ . . . body” and “. . . structure” may have multiple meanings, such as a single part or multiple parts.
Ordinal numbers such as “first” and “second” are merely terms for identifying configurations, and do not have other meanings (for example, a specific order). For example, the presence of a “first element” does not imply that a “second element” is present, and the presence of a “second element” does not imply that a “first element” is present.
Terms such as “substantially”, “about”, and “approximately” indicating the degree may mean a reasonable amount of deviation such that the final result is not significantly changed unless otherwise specified in the embodiments. All numerical values recited in this application can be construed to include language such as “substantially,” “about,” and “approximately.”
The phrase “at least one of A and B” in this application should be interpreted to include only A, only B, and both A and B.
Obviously, many modifications and variations of the present invention are possible in light of the above teachings. Accordingly, the invention may be practiced otherwise than as specifically disclosed herein without departing from the spirit of the invention.
Number | Date | Country | Kind |
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JP2020-171755 | Oct 2020 | JP | national |
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Number | Date | Country |
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2020-12350 | Jan 2020 | JP |
Number | Date | Country | |
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20220112689 A1 | Apr 2022 | US |