JP2014084558A - Work vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a work vehicle capable of suppressing enlargement of the vehicle while maintaining a driving speed of a hydraulic actuator.SOLUTION: A main pump unit has a first main pump and a second main pump. The first main pump and the second main pump are connected mutually in series. A first hydraulic circuit connects the main pump unit with a first hydraulic actuator. A work machine pump unit has a first work machine pump and a second work machine pump. The first work machine pump and the second work machine pump are connected mutually in series. A second hydraulic circuit connects the work machine pump unit with a second hydraulic actuator to form a closed circuit. A power takeout device connects the main pump unit and the work machine pump unit in parallel with each other to a power source. The power takeout device increases the rotational speed from the power source and transfers it to the work machine pump unit.

Description

  The present invention relates to a work vehicle.

  A work vehicle such as a hydraulic excavator or a wheel loader includes a work machine driven by a hydraulic actuator. A hydraulic closed circuit for supplying hydraulic oil to the hydraulic actuator has been proposed (see, for example, Patent Document 1). When the hydraulic circuit forms a closed circuit, it is possible to regenerate the potential energy of the work implement and reduce the fuel consumption of the power source.

JP 2003-21104 A

  Currently, work vehicles in which the hydraulic circuit forms an open circuit instead of a closed circuit as described above are generally used (hereinafter referred to as “current work vehicle”). In such a current work vehicle, the hydraulic circuit connects two hydraulic pumps and a hydraulic actuator, and hydraulic pressure is generated by hydraulic fluid from one hydraulic pump or combined hydraulic fluid from two hydraulic pumps. The actuator is driven. For example, when an operation of raising the boom is performed, the hydraulic oils of the two hydraulic pumps are merged and supplied to the boom cylinder. Thereby, since the raising speed of a boom becomes high, work efficiency improves. Or when operation which pulls an arm is performed, the hydraulic fluid of two hydraulic pumps merges and is supplied to an arm cylinder. Thereby, since the pulling speed of the arm is increased, work efficiency is improved.

  In the above-described current work vehicle, when the hydraulic closed circuit technology is applied to the hydraulic circuit for driving the hydraulic actuator, the following problems occur. Here, a hydraulic circuit for driving the boom (hereinafter referred to as “boom circuit”) will be described as an example.

  In order to make the boom circuit a closed circuit, a boom pump for driving the boom cylinder is required in addition to the main pump for driving other hydraulic actuators. Therefore, a total of four hydraulic pumps including two main pumps and two boom pumps are required. Further, a power take-out device for transmitting the output of the power source to the four hydraulic pumps is also required. It is difficult to arrange these drive devices in the work vehicle without increasing the size of the vehicle.

  Furthermore, in order to make the boom drive speed equal to that of the current work vehicle, the capacity of the boom pump needs to be approximately the same as the capacity of the hydraulic pump of the current work vehicle. In this case, it is difficult to reduce the size of the boom pump. Therefore, it is more difficult to arrange the driving device in the work vehicle without reducing the boom driving speed.

  The subject of this invention is providing the work vehicle which can suppress the enlargement of a vehicle, maintaining the drive speed of a hydraulic actuator.

  A work vehicle according to a first aspect of the present invention includes a power source, a main pump unit, a first hydraulic actuator, a first hydraulic circuit, a work implement pump unit, a second hydraulic actuator, 2 hydraulic circuit and a power take-out device. The main pump unit has a first main pump and a second main pump. The first main pump and the second main pump are connected to each other in series and are driven by a power source. The first hydraulic actuator is driven by hydraulic oil from the main pump unit. The first hydraulic circuit connects the main pump unit and the first hydraulic actuator. The work machine pump unit includes a first work machine pump and a second work machine pump. The first work machine pump and the second work machine pump are connected to each other in series and are driven by a power source. The second hydraulic actuator is driven by hydraulic oil from the work implement pump unit. The second hydraulic circuit connects the work implement pump unit and the second hydraulic actuator to form a closed circuit. The power take-out device connects the main pump unit and the work machine pump unit to the power source in parallel with each other. The power take-out device increases the rotation from the power source and transmits it to the work implement pump unit.

  A work vehicle according to a second aspect of the present invention is the work vehicle according to the first aspect, wherein the maximum capacity of the work implement pump unit is smaller than the maximum capacity of the main pump unit.

  The work vehicle according to the third aspect of the present invention is the work vehicle according to the first or second aspect, and further includes a hydraulic oil tank. The first hydraulic circuit has a first tank flow path. The first tank channel is connected to the hydraulic oil tank. The second hydraulic circuit has a second tank flow path. The second tank channel is connected to the hydraulic oil tank. Either the first main pump or the second main pump has a first pump port to which the first tank flow path is connected. Either the first work machine pump or the second work machine pump has a second pump port to which the second tank flow path is connected. The second pump port is disposed below the first pump port.

  A work vehicle according to a fourth aspect of the present invention is the work vehicle according to the first or second aspect, and further includes a hydraulic oil tank. The main pump unit is disposed between the hydraulic oil tank and the work machine pump unit.

  A work vehicle according to a fifth aspect of the present invention is the work vehicle according to any one of the first to fourth aspects, and further includes a counterweight disposed at a rear portion of the vehicle. The work implement pump unit is disposed between the counterweight and the main pump unit.

  The work vehicle according to a sixth aspect of the present invention is the work vehicle according to any one of the first to fifth aspects, wherein the power take-out device transmits the rotation from the power source to the main pump unit at the same speed. .

  A work vehicle according to a seventh aspect of the present invention is the work vehicle according to any one of the first to sixth aspects, wherein the power source and the main pump unit are arranged side by side in the vehicle width direction. The axis of the drive shaft of the work machine pump unit is disposed rearward and downward with respect to the axis of the drive shaft of the main pump unit.

  A work vehicle according to an eighth aspect of the present invention is the work vehicle according to any one of the first to seventh aspects, and further includes a vehicle body frame that supports a power source. The power source and the main pump unit are arranged side by side in the vehicle width direction. In a side view, at least a part of the work implement pump unit is disposed so as to overlap the body frame.

In the work vehicle according to the first aspect of the present invention, the main pump unit and the work implement pump unit are connected to the power source in parallel with each other via the power take-off device. Then, the power take-out device accelerates the rotation from the power source and transmits it to the work implement pump unit. For this reason,
The work implement pump unit can be reduced in size while maintaining the driving speed of the second hydraulic actuator. Thereby, the enlargement of a vehicle is suppressed.

  In the work vehicle according to the second aspect of the present invention, the maximum capacity of the work implement pump unit is smaller than the maximum capacity of the main pump unit. For this reason, a working machine pump unit can be reduced in size easily. Thereby, the enlargement of a vehicle is suppressed.

  In the work vehicle according to the third aspect of the present invention, the second pump port is disposed below the first pump port. For this reason, the work implement pump unit can easily suck the required amount of hydraulic oil according to the increase in the rotation speed of the work implement pump unit.

  In the work vehicle according to the fourth aspect of the present invention, the main pump unit is disposed between the hydraulic oil tank and the work implement pump unit. For this reason, the main pump unit can be disposed near the hydraulic oil tank.

  In the work vehicle according to the fifth aspect of the present invention, the work implement pump unit is disposed between the counterweight and the main pump unit. Accordingly, the work machine pump unit is disposed near the counterweight. That is, a heavy object is disposed at the rear of the vehicle. Thereby, the stability of the vehicle is improved.

  In the work vehicle according to the sixth aspect of the present invention, the number of gear teeth used in the power take-off device can be reduced. For this reason, a power take-out device can be reduced in size.

  In the work vehicle according to the seventh aspect of the present invention, the work implement pump unit and the main pump unit can be arranged in a compact manner as compared with the case where the work implement pump unit is arranged immediately behind the main pump unit.

  In the work vehicle according to the eighth aspect of the present invention, at least a part of the work implement pump unit is disposed so as to overlap the vehicle body frame in a side view. For this reason, the work machine pump unit and the vehicle body frame can be arranged in a compact manner.

1 is a perspective view of a work vehicle according to an embodiment of the present invention. The block diagram which shows the structure of the hydraulic drive system of a working vehicle. The perspective view which shows the internal structure of the engine room of a work vehicle. The side view which shows the internal structure of an engine room.

  Hereinafter, a hydraulic excavator according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of a hydraulic excavator 100. The excavator 100 includes a work machine 2, an upper swing body 3, and a lower vehicle body 5.

  The upper swing body 3 is placed on the lower vehicle body 5. The upper swing body 3 is provided so as to be swingable with respect to the lower vehicle body 5. The upper swing body 3 includes a cab 4, an engine room 6, a hydraulic oil tank 7, and a counterweight 8. The cab 4 is placed at the front of the upper swing body 3. The engine room 6 is disposed behind the cab 4. The engine room 6 accommodates devices such as an engine and a hydraulic pump described later.

  The hydraulic oil tank 7 is disposed in front of the engine room 6. The counterweight 8 is disposed at the rear of the vehicle. The counterweight 8 is disposed behind the engine room 6. The lower vehicle body 5 has crawler belts 5a and 5b. As the crawler belts 5a and 5b rotate, the excavator 100 travels.

  The work machine 2 is attached to the front part of the upper swing body 3. The work machine 2 includes a boom 90, an arm 91, and a bucket 92. In addition, the work machine 2 includes hydraulic actuators such as a boom cylinder 93, an arm cylinder 94, and a bucket cylinder 95.

  A base end portion of the boom 90 is swingably attached to the upper swing body 3 via a boom pin 96. A base end portion of the arm 91 is swingably attached to a distal end portion of the boom 90 via an arm pin 97. A bucket 92 is swingably attached to the tip of the arm 91 via a bucket pin 98.

  The boom cylinder 93, the arm cylinder 94, and the bucket cylinder 95 are hydraulic cylinders that are driven by hydraulic pressure. The boom cylinder 93 drives the boom 90. The arm cylinder 94 drives the arm 91. The bucket cylinder 95 drives the bucket 92.

  FIG. 2 is a block diagram illustrating a configuration of the hydraulic drive system 1 included in the excavator 100. The hydraulic drive system 1 includes a power source 11, a main pump unit 12, a work machine pump unit 13, and a power take-out device 14. The power source 11 is an engine, for example. The power source 11 drives the main pump unit 12 and the work machine pump unit 13.

  The main pump unit 12 includes a first main pump 15 and a second main pump 16. The first main pump 15 and the second main pump 16 are connected in series with each other. For example, the drive shaft of the first main pump 15 and the drive shaft of the second main pump 16 are arranged in series and are connected to each other by coupling. The first main pump 15 and the second main pump 16 are driven by the power source 11 to discharge hydraulic oil. The first main pump 15 and the second main pump 16 are variable displacement hydraulic pumps. In addition, it is preferable that the drive shaft that outputs the power of the power source 11 and the drive shaft of the main pump unit 12 are arranged on the same shaft.

  The hydraulic drive system 1 includes a first hydraulic actuator 17 and a first hydraulic circuit 18. The first hydraulic actuator 17 is driven by hydraulic oil from the main pump unit 12. The first hydraulic actuator 17 includes, for example, a traveling motor 17a and a turning motor 17b. The traveling motor 17a is driven by hydraulic oil from the main pump unit 12 to rotate the crawler belts 5a and 5b. The turning motor 17 b is driven by hydraulic oil from the main pump unit 12 to turn the upper turning body 3. The first hydraulic actuator 17 includes the bucket cylinder 95 and the arm cylinder 94 described above.

  The first hydraulic circuit 18 connects the main pump unit 12 and the first hydraulic actuator 17. The first hydraulic circuit 18 constitutes an open circuit. The first hydraulic circuit 18 includes a first tank channel 21, a first supply channel 22, and a second supply channel 23.

  The first tank channel 21 is connected to the hydraulic oil tank 7. The first tank channel 21 is connected to the first suction port 15 b of the first main pump 15 and the second suction port 16 b of the second main pump 16. The first main pump 15 sucks the hydraulic oil from the first suction port 15b and discharges the hydraulic oil from the first discharge port 15a. The second main pump 16 sucks the hydraulic oil from the second suction port 16b and discharges the hydraulic oil from the second discharge port 16a. The first suction port 15b or the second suction port 16b is an example of the first pump port of the present invention.

  The first supply channel 22 is connected to the first discharge port 15a. The first supply flow path 22 is connected to the first hydraulic actuator 17 via the main control valve 24. The second supply channel 23 is connected to the second discharge port 16a. The second supply channel 23 is connected to the first hydraulic actuator 17 via the main control valve 24. The main control valve 24 includes a spool corresponding to each actuator of the first hydraulic actuator 17. For example, the hydraulic oil in the first supply flow path 22 is sent to the bucket cylinder 95 via the bucket spool in the main control valve 24. The hydraulic oil in the second supply passage 23 is sent to the turning motor 17 b via the turning spool in the main control valve 24. The hydraulic oil in the first supply channel 22 is sent to the arm cylinder 94 via the first arm spool in the main control valve 24. The hydraulic oil in the second supply flow path 23 is sent to the arm cylinder 94 via the second arm spool in the main control valve 24. That is, the hydraulic oil discharged from the first main pump 15 and the second main pump 16 merges and is sent to the arm cylinder 94.

  The work machine pump unit 13 includes a first work machine pump 25 and a second work machine pump 26. The first work machine pump 25 and the second work machine pump 26 are connected in series with each other. For example, the drive shaft of the first work machine pump 25 and the drive shaft of the second work machine pump 26 are arranged in series and are connected to each other by coupling. The first work machine pump 25 and the second work machine pump 26 are driven by the power source 11 to discharge hydraulic oil. The first work machine pump 25 and the second work machine pump 26 are variable displacement hydraulic pumps.

  The maximum capacity of the work machine pump unit 13 is smaller than the maximum capacity of the main pump unit 12. Specifically, the maximum capacity of the first work machine pump 25 is smaller than the maximum capacity of the first main pump 15. The maximum capacity of the first work machine pump 25 is smaller than the maximum capacity of the second main pump 16. The maximum capacity of the second work machine pump 26 is smaller than the maximum capacity of the first main pump 15. The maximum capacity of the second work machine pump 26 is smaller than the maximum capacity of the second main pump 16.

  The first work machine pump 25 and the second work machine pump 26 are two-way discharge hydraulic pumps. Specifically, the first work machine pump 25 includes a first pump port 25a and a second pump port 25b. The first work machine pump 25 can be switched between a first discharge state and a second discharge state. In the first discharge state, the first work machine pump 25 is supplied with hydraulic oil to the second pump port 25b and discharges the hydraulic oil from the first pump port 25a. In the second discharge state, the first work machine pump 25 is supplied with hydraulic oil to the first pump port 25a and discharges hydraulic oil from the second pump port 25b.

  The second work machine pump 26 includes a first pump port 26a and a second pump port 26b. Similar to the first work machine pump 25, the second work machine pump 26 can be switched between a first discharge state and a second discharge state. In the first discharge state, the second working machine pump 26 is supplied with hydraulic oil to the second pump port 26b and discharges the hydraulic oil from the first pump port 26a. In the second discharge state, the second working machine pump 26 is supplied with hydraulic oil to the first pump port 26a and discharges hydraulic oil from the second pump port 26b.

  The hydraulic drive system 1 includes a second hydraulic actuator 27 and a second hydraulic circuit 28. The second hydraulic actuator 27 is driven by hydraulic oil from the work machine pump unit 13. The second hydraulic actuator 27 is a hydraulic cylinder. Specifically, the second hydraulic actuator 27 is the boom cylinder 93 described above.

  The second hydraulic actuator 27 has a cylinder rod 27a and a cylinder tube 27b. The cylinder rod 27a partitions the inside of the cylinder tube 27b into a first chamber 27c and a second chamber 27d. The second hydraulic actuator 27 expands and contracts by switching between supply and discharge of hydraulic oil to and from the first chamber 27c and the second chamber 27d. Specifically, the hydraulic oil is supplied to the first chamber 27c, and the hydraulic oil is discharged from the second chamber 27d, whereby the cylinder rod 27a extends. When the hydraulic oil is supplied to the second chamber 27d and the hydraulic oil is discharged from the first chamber 27c, the cylinder rod contracts.

  The pressure receiving area of the cylinder rod 27a in the first chamber 27c is larger than the pressure receiving area of the cylinder rod 27a in the second chamber 27d. Accordingly, when the second hydraulic actuator 27 is extended, a larger amount of hydraulic oil than the hydraulic oil discharged from the second chamber 27d is supplied to the first chamber 27c. When the second hydraulic actuator 27 is contracted, a larger amount of hydraulic oil than the hydraulic oil supplied to the second chamber 27d is discharged from the first chamber 27c.

  The second hydraulic circuit 28 connects the work implement pump unit 13 and the second hydraulic actuator 27. The second hydraulic circuit 28 forms a closed circuit between the work machine pump unit 13 and the second hydraulic actuator 27. The second hydraulic circuit 28 includes a first flow path 31, a second flow path 32, and a second tank flow path 33.

  The first flow path 31 connects the first chamber 27 c of the second hydraulic actuator 27 and the first pump port 25 a of the first work machine pump 25. The first flow path 31 is a flow path for supplying hydraulic oil to the first chamber 27 c of the second hydraulic actuator 27 or collecting the hydraulic oil from the first chamber 27 c of the second hydraulic actuator 27. . The first flow path 31 is also connected to the first pump port 26 a of the second work machine pump 26. Accordingly, the hydraulic fluid from both the first work machine pump 25 and the second work machine pump 26 is supplied to the first flow path 31.

  The second flow path 32 is connected to the second chamber 27 d of the second hydraulic actuator 27 and the second pump port 25 b of the first work machine pump 25. The second flow path 32 is a flow path for supplying hydraulic oil to the second chamber 27 d of the second hydraulic actuator 27 or for collecting the hydraulic oil from the second chamber 27 d of the second hydraulic actuator 27. .

  The second tank flow path 33 is connected to the hydraulic oil tank 7. The second tank flow path 33 is connected to the second pump port 26 b of the second work machine pump 26.

  The hydraulic drive system 1 further includes a charge pump 34. The charge pump 34 is a hydraulic pump for replenishing the second hydraulic circuit 28 with hydraulic oil. The charge pump 34 discharges hydraulic oil when driven by the power source 11. The charge pump 34 is a fixed displacement hydraulic pump.

  The second hydraulic circuit 28 further has a charge flow path 35. The charge channel 35 connects the charge pump 34 and the first channel 31. The charge channel 35 connects the charge pump 34 and the second channel 32. Specifically, the charge flow path 35 is connected to the first flow path 31 via the check valve 41a. The check valve 41a is opened when the hydraulic pressure of the first flow path 31 becomes lower than the hydraulic pressure of the charge flow path 35. The charge flow path 35 is connected to the second flow path 32 via the check valve 41b. The check valve 41b is opened when the hydraulic pressure of the second flow path 32 becomes lower than the hydraulic pressure of the charge flow path 35.

  The charge flow path 35 is connected to the hydraulic oil tank 7 via a charge relief valve 42. The charge relief valve 42 maintains the hydraulic pressure of the charge flow path 35 at a predetermined charge pressure. When the hydraulic pressure of the first flow path 31 or the second flow path 32 becomes lower than the hydraulic pressure of the charge flow path 35, the hydraulic oil from the charge pump 34 passes through the charge flow path 35 and the first flow path 31 or the second flow path. 32. Thereby, the hydraulic pressure of the first flow path 31 and the second flow path 32 is maintained at a predetermined value or more.

  The second hydraulic circuit 28 further has a relief flow path 36. The relief channel 36 is connected to the first channel 31 via a check valve 41c. The check valve 41c is opened when the hydraulic pressure of the first flow path 31 becomes higher than the hydraulic pressure of the relief flow path 36. The relief flow path 36 is connected to the second flow path 32 via a check valve 41d. The check valve 41d is opened when the hydraulic pressure of the second flow path 32 becomes higher than the hydraulic pressure of the relief flow path 36. The relief flow path 36 is connected to the charge flow path 35 via a relief valve 43. The relief valve 43 maintains the pressure of the relief flow path 36 below a predetermined relief pressure. Thereby, the hydraulic pressure of the first flow path 31 and the second flow path 32 is maintained below a predetermined relief pressure.

  When the second hydraulic actuator 27 is extended, the first work machine pump 25 and the second work machine pump 26 are driven in the first discharge state. Thereby, the work machine pump unit 13 is in a state of supplying the hydraulic oil to the first chamber 27c and sucking the hydraulic oil from the second chamber 27d. Specifically, the hydraulic oil discharged from the first pump port 25a of the first work machine pump 25 and the first pump port 26a of the second work machine pump 26 passes through the first flow path 31 and passes through the first flow path 31. 2 is supplied to the first chamber 27 c of the second hydraulic actuator 27. Further, the hydraulic oil in the second chamber 27 d of the second hydraulic actuator 27 passes through the second flow path 32 and is collected in the second pump port 25 b of the first work machine pump 25. As a result, the second hydraulic actuator 27 extends.

  When the second hydraulic actuator 27 is contracted, the first work machine pump 25 and the second work machine pump 26 are driven in the second discharge state. Thereby, the work machine pump unit 13 is in a state of supplying the hydraulic oil to the second chamber 27d and sucking the hydraulic oil from the first chamber 27c. Specifically, the hydraulic oil discharged from the second pump port 25 b of the first work machine pump 25 is supplied to the second chamber 27 d of the second hydraulic actuator 27 through the second flow path 32. Further, the hydraulic oil in the first chamber 27 c of the second hydraulic actuator 27 passes through the first flow path 31 and passes through the first pump port 25 a of the first work machine pump 25 and the first pump of the second work machine pump 26. It is collected in the port 26a. As a result, the second hydraulic actuator 27 contracts.

  The power take-out device 14 has one side connected to the power source 11 and the other side connected in parallel to the main pump unit 12 and the work implement pump unit 13. The power take-out device 14 is a gear device that transmits the rotation from the power source 11 to the main pump unit 12 and the work machine pump unit 13. The power take-out device 14 accelerates the rotation from the power source 11 and transmits it to the work machine pump unit 13. The power take-out device 14 transmits the rotation from the power source 11 to the main pump unit 12 at the same speed.

  Next, the internal structure of the engine room 6 will be described. FIG. 3 is a perspective view showing the internal structure of the engine room 6. FIG. 4 is a side view showing the internal structure of the engine room 6.

  As shown in FIGS. 3 and 4, the work vehicle 100 has a body frame 50. The vehicle body frame 50 supports the power source 11. The vehicle body frame 50 includes a main frame 51, a first side frame 52, and a second side frame 53.

  The main frame 51 extends in the vehicle front-rear direction. The power source 11 is disposed on the main frame 51. A counterweight 8 is disposed at the rear of the main frame 51. The first side frame 52 is disposed on one side of the main frame 51. The first side frame 52 extends in the vehicle front-rear direction. The hydraulic oil tank 7 is disposed between the main frame 51 and the first side frame 52 in the vehicle width direction. The second side frame 53 is disposed on the other side of the main frame 51. The second side frame 53 extends in the vehicle front-rear direction.

  The work vehicle 100 has a cooling device 19. The cooling device 19 has a blower fan and a radiator (not shown). The cooling device 19 cools the coolant of the power source 11. The cooling device 19 is disposed between the main frame 51 and the second side frame 53 in the vehicle width direction.

  As shown in FIG. 3, the cooling device 19, the power source 11, the power take-out device 14, the second main pump 16, and the first main pump 15 are arranged side by side in the vehicle width direction. The main pump unit 12 is disposed between the hydraulic oil tank 7 and the work machine pump unit 13. The work machine pump unit 13 is disposed between the counterweight 8 and the main pump unit 12. The main pump unit 12 and the work implement pump unit 13 are disposed between the main frame 51 and the first side frame 52 in the vehicle width direction.

  As illustrated in FIG. 4, the axis Ax2 of the drive shaft of the work machine pump unit 13 is disposed rearward and downward with respect to the axis Ax1 of the drive shaft of the main pump unit 12. The bottom of the work machine pump unit 13 is located below the bottom of the main pump unit 12. In the side view, at least a part of the work machine pump unit 13 is disposed so as to overlap the main frame 51.

  The second pump port 26b of the second work implement pump 26 is disposed below the first suction port 15b and the second suction port 16b. The 1st tank channel 21 and the 2nd tank channel 33 are constituted by piping. At least a part of the second tank channel 33 is located below the first tank channel 21.

  The work vehicle 100 according to the present embodiment has the following features.

  A main pump unit 12 and a work machine pump unit 13 are connected to the power source 11 in parallel with each other via a power take-out device 14. The power take-out device 14 accelerates the rotation from the power source 11 and transmits it to the work machine pump unit 13. For this reason, the work implement pump unit 13 can be reduced in size while maintaining the driving speed of the second hydraulic actuator 27. Thereby, the enlargement of a vehicle is suppressed.

  The maximum capacity of the work machine pump unit 13 is smaller than the maximum capacity of the main pump unit 12. Therefore, the work machine pump unit 13 can be easily downsized. Thereby, the enlargement of a vehicle is suppressed.

  The second pump port 26b of the second work implement pump 26 is disposed below the first suction port 15b and the second suction port 16b. For this reason, the hydraulic oil from the hydraulic oil tank 7 tends to flow into the second pump port 26b. As a result, the work implement pump unit 13 can easily suck the required amount of hydraulic oil according to the increase in the rotation speed of the work implement pump unit 13.

  The main pump unit 12 is disposed between the hydraulic oil tank 7 and the work machine pump unit 13. For this reason, the main pump unit 12 can be disposed near the hydraulic oil tank 7.

  The work machine pump unit 13 is disposed between the counterweight 8 and the main pump unit 12. Accordingly, the work machine pump unit 13 is disposed near the counterweight 8. That is, a heavy object is disposed at the rear of the vehicle. Thereby, the stability of the vehicle is improved.

  The power take-out device 14 transmits the rotation from the power source 11 to the main pump unit 12 at the same speed. Therefore, the number of gear teeth used in the power take-out device 14 can be reduced. For this reason, the power take-out device 14 can be reduced in size.

  A work machine pump unit 13 is disposed behind and below the main pump unit 12. For this reason, compared with the case where the working machine pump unit 13 is arrange | positioned just behind the main pump unit 12, the working machine pump unit 13 and the main pump unit 12 can be arrange | positioned compactly.

  In a side view, at least a part of the work machine pump unit 13 is disposed so as to overlap the main frame 51. For this reason, the work machine pump unit 13 and the vehicle body frame 50 can be arranged in a compact manner.

  As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the summary of invention.

  In the above embodiment, a hydraulic excavator is exemplified as the work vehicle 100. However, the work vehicle of the present invention is not limited to a hydraulic excavator, and may be another type of vehicle such as a wheel loader.

  The power source is not limited to the engine but may be an electric motor. The first hydraulic actuator of the present invention is not limited to the hydraulic actuator exemplified in the above embodiment. The second hydraulic actuator of the present invention is not limited to the boom cylinder exemplified in the above embodiment. However, since the potential energy of the boom is larger than the energy obtained from other members, a lot of energy can be regenerated by making the hydraulic circuit for driving the boom cylinder a closed circuit.

  In the above embodiment, the output shaft of the power source 11 and the drive shaft of the main pump unit 12 are arranged on the same axis. However, if the axis Ax2 of the drive shaft of the work machine pump unit is disposed behind and below the axis Ax1 of the drive shaft of the main pump unit 12, the output shaft of the power source 11 and the drive shaft of the main pump unit 12 are the same. It does not have to be on the axis. That is, the arrangement of the axis Ax1 of the main pump unit 12 and the output shaft of the power source 11 may be different from the arrangement of the above embodiment.

  ADVANTAGE OF THE INVENTION According to this invention, the work vehicle which can suppress the enlargement of a vehicle can be provided, maintaining the drive speed of a hydraulic actuator.

11 power source 15 first main pump 16 second main pump 12 main pump unit 17 first hydraulic actuator 18 first hydraulic circuit 25 first work machine pump 26 second work machine pump 13 work machine pump unit 27 second Hydraulic actuator 28 Second hydraulic circuit 14 Power take-out device 7 Hydraulic oil tank 21 First tank flow path 33 Second tank flow path 15b First suction port (first pump port)
26b Second pump port 8 Counterweight 50 Body frame

Claims (8)

Power source,
A main pump unit having a first main pump and a second main pump connected to each other in series and driven by the power source;
A first hydraulic actuator driven by hydraulic oil from the main pump unit;
A first hydraulic circuit connecting the main pump unit and the first hydraulic actuator;
A work machine pump unit having a first work machine pump and a second work machine pump connected to each other in series and driven by the power source;
A second hydraulic actuator driven by hydraulic fluid from the work implement pump unit;
A second hydraulic circuit connecting the working machine pump unit and the second hydraulic actuator to form a closed circuit;
A power take-off device that connects the main pump unit and the work implement pump unit to the power source in parallel with each other, and accelerates rotation from the power source and transmits the rotation to the work implement pump unit;
Work vehicle equipped with. The maximum capacity of the work machine pump unit is smaller than the maximum capacity of the main pump unit,
The work vehicle according to claim 1. A hydraulic oil tank,
The first hydraulic circuit has a first tank flow path connected to the hydraulic oil tank,
The second hydraulic circuit has a second tank flow path connected to the hydraulic oil tank,
Either the first main pump or the second main pump has a first pump port to which the first tank flow path is connected,
Either the first work machine pump or the second work machine pump has a second pump port to which the second tank flow path is connected,
The second pump port is disposed below the first pump port;
The work vehicle according to claim 1 or 2. A hydraulic oil tank,
The main pump unit is disposed between the hydraulic oil tank and the work machine pump unit.
The work vehicle according to claim 1 or 2. A counterweight disposed at the rear of the vehicle;
The work implement pump unit is disposed between the counterweight and the main pump unit.
The work vehicle according to any one of claims 1 to 4. The power take-out device transmits rotation from the power source to the main pump unit at the same speed.
The work vehicle according to any one of claims 1 to 5. The power source and the main pump unit are arranged side by side in the vehicle width direction,
The axis of the drive shaft of the work implement pump unit is disposed rearward and downward with respect to the axis of the drive shaft of the main pump unit
The work vehicle according to any one of claims 1 to 6. A vehicle body frame for supporting the power source;
The power source and the main pump unit are arranged side by side in the vehicle width direction,
In a side view, at least a part of the work machine pump unit is disposed so as to overlap the body frame.
The work vehicle according to any one of claims 1 to 7.

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