JP6758278B2 - Work vehicle - Google Patents

Description

The present invention relates to a work vehicle suitable for traveling on an uneven road surface.

Conventionally, four traveling wheels are supported on the vehicle body via a link mechanism having two joints and can be bent and stretched, and the link mechanism is equipped with an electric motor, a reduction mechanism, etc. to drive the electric motor. In some cases, the link mechanism can be flexed and extended by force (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 9-142347

The wheel support structure in the above-mentioned conventional configuration makes it possible to maintain the main body in an appropriate posture while bending and stretching the link mechanism even if the traveling road surface is uneven. Therefore, it is conceivable to apply such a wheel support structure to an agricultural work vehicle traveling on a work site having an uneven traveling road surface. However, the wheel support structure in the above-mentioned conventional configuration has been difficult to adopt for agricultural work vehicles.

To add an explanation, in agricultural work vehicles, a large amount of fine dust such as dust generated during running and floating dust generated from crops during harvesting work may be generated in the vicinity of the work vehicle, and rainwater. Moisture may adhere due to morning dew or the like. In the above conventional configuration, the link mechanism for supporting the traveling wheels is bent and stretched by the built-in electric motor. Therefore, when fine dust or moisture enters the inside of the link mechanism, the electric motor or deceleration is performed. There is a risk of malfunction in the mechanism, etc.

In order to eliminate the above-mentioned disadvantages, it is conceivable to use a hydraulic cylinder instead of the electric motor as a driving means for changing the posture of the link mechanism. Further, in this type of work vehicle, in addition to the hydraulic cylinder for the attitude change operation of the link mechanism, a drive device for driving the traveling device is required, but the traveling device is via the link mechanism capable of changing the attitude. The configuration is supported by the vehicle body, and if the driving force is supplied from the vehicle body side via a mechanical transmission mechanism such as a gear or a chain, the configuration becomes complicated. Therefore, it is conceivable to use a hydraulic motor or the like to drive the traveling device.

In such a configuration including a plurality of hydraulic drive devices, for example, it is conceivable to drive the hydraulic pump by a drive source such as an engine to supply hydraulic oil to the plurality of hydraulic drive devices. .. In this configuration, when traveling on an uneven work site, the hydraulic motor for driving the traveling and the hydraulic cylinder for changing the posture may be operated at the same time.

This type of work vehicle does not generate a large drive load like, for example, a tractor, but has a small vehicle body and is often mainly used for work with a relatively light load. The engine is often installed. When such a small engine is installed, when the hydraulic motor for driving and the hydraulic cylinder for changing the attitude are operated at the same time, a large flow rate of hydraulic oil is used for the hydraulic motor, and the hydraulic pressure for changing the attitude There is a risk that the posture of the vehicle body will become unstable due to insufficient hydraulic pressure in the cylinder.

Therefore, in a work environment where fine dust, moisture, etc. may enter, a work vehicle capable of carrying out work while maintaining an appropriate posture of the vehicle body is desired even in a work place with many irregularities. It was.

The characteristic configuration of the work vehicle according to the present invention is
With the vehicle body
With multiple traveling devices to drive
A plurality of vehicle body support portions that support the plurality of traveling devices separately with respect to the vehicle body so that the height position can be changed.
A plurality of hydraulic motors for driving the plurality of traveling devices separately,
A plurality of hydraulic cylinders capable of changing and operating a plurality of the vehicle body support portions,
A first hydraulic pump that supplies pressure oil to the plurality of hydraulic motors,
A second hydraulic pump, which supplies pressure oil to multiple hydraulic cylinders , is provided.
The first hydraulic pump is driven by an engine, and the second hydraulic pump is driven by an electric motor.
An oil passage switching means capable of switching between a state in which pressure oil from the first hydraulic pump is supplied to the plurality of hydraulic motors and a state in which pressure oil from the second hydraulic pump is supplied to the plurality of hydraulic motors. It is in the point that it is provided .

According to the present invention, pressure oil is supplied from the first hydraulic pump to the hydraulic motor to drive the traveling device to drive the work vehicle. On the other hand, pressure oil is supplied from the second hydraulic pump to a plurality of hydraulic cylinders to change the height position of the traveling device with respect to the vehicle body. As a result, even if a large amount of pressure oil required for traveling is supplied to the hydraulic motor, the supply state of the pressure oil to the hydraulic cylinder is not affected, and the posture of the vehicle body is changed with respect to the unevenness of the ground while traveling. The operation can be performed well.

Moreover, since the hydraulic motor and the hydraulic cylinder are operated by the pressure oil sent from the hydraulic pump, even if fine dust or moisture may enter, it is adversely affected by the intrusion and causes malfunctions. There is little risk of causing it.

Further , according to this configuration, the hydraulic motor is supplied by the first hydraulic pump driven by the engine to the hydraulic motor that requires a large flow rate of the hydraulic oil to drive the traveling device. A sufficient amount of hydraulic oil can be supplied to the vehicle. On the other hand, since pressure oil is supplied to the hydraulic cylinder for changing the posture by the first hydraulic pump driven by the electric motor, for example, when performing the posture changing operation while the work vehicle is running, for example. Even when a large amount of pressure oil is supplied to the hydraulic motor, the supply of pressure oil to the hydraulic cylinder is not affected, so that the posture of the vehicle body is less likely to become uncertain. In addition, when the work vehicle is stopped and it is necessary to change the posture of the vehicle body, pressure oil can be supplied by driving the electric motor with the engine stopped, reducing noise. At the same time, it has the advantage of reducing fuel consumption.

Further, according to this configuration, when the oil passage switching means is switched to a state in which the pressure oil from the first hydraulic pump driven by the engine is supplied to a plurality of hydraulic motors, a large amount of pressure oil is applied to the hydraulic motors. It can be supplied in a stable state. For example, stable traveling can be performed when traveling on a rough road with severe unevenness, when traveling for a long time, when traveling at a high speed, or the like.

When the oil passage switching means is switched to a state in which the pressure oil from the second hydraulic pump driven by the electric motor is supplied to the plurality of hydraulic motors, the running drive can be performed with the engine stopped. For example, when it is desired to change the position of the vehicle body slightly, or when the work vehicle is loaded or unloaded on a driving vehicle or the like, it can be moved and traveled while making fine adjustments.

By switching the hydraulic pump to be used according to such a difference in working conditions, it is possible to obtain a pressure oil supply state suitable for the working conditions at that time, which is convenient.

In the present invention, the elevating support mechanism is an articulated link mechanism in which a plurality of links are pivotally connected so as to have at least two or more joints, and the traveling device is movably supported on the vehicle body. It is preferable that the structure is configured.

According to this configuration, by supporting the traveling device by using the articulated link mechanism, the height adjustment range of the traveling device with respect to the vehicle body can be widened, and the vehicle can be used even if there are large irregularities on the traveling road surface. It is possible to run while maintaining the main body in a posture suitable for work.

It is an overall side view of a work vehicle. It is an overall plan view of a work vehicle. It is a top view of the refraction link mechanism. It is a side view of the refraction link mechanism. It is a front view which shows the refraction link mechanism in the removed state. It is a front view which shows the refraction link mechanism in the attached state. It is a top view which shows the left turning state by a turning mechanism. It is a top view which shows the right-handed turning state by a turning mechanism. It is a hydraulic system diagram. It is explanatory drawing of the four-wheel running state. It is explanatory drawing of the two-wheel running state. It is explanatory drawing of the two-wheel running state. It is a side view of a free-moving state. It is a side view of the state of getting over a step. It is a top view of the article transport state. It is a side view of the article transport state. It is a side view of the slope running state. It is a front view of the straddling running state. It is a hydraulic system diagram of a reference embodiment. It is a hydraulic system diagram of this embodiment.

Hereinafter, embodiments of the work vehicle according to the present invention will be described with reference to the drawings.

[Reference Embodiment]
As shown in FIGS. 1 and 2, the work vehicle includes a vehicle body 1 having a substantially rectangular frame shape that supports the entire vehicle, and a plurality of (specifically, four) traveling devices 2 driven by hydraulic motors 9. , A plurality of auxiliary wheels 3 provided corresponding to each of the plurality of traveling devices 2, and a refraction link mechanism 4 as a vehicle body support portion that supports the plurality of traveling devices 2 on the vehicle body 1 so that the positions of the plurality of traveling devices 2 can be freely changed. A plurality of hydraulic cylinders 5 and 6 capable of changing and operating the refraction link mechanism 4 and a hydraulic oil supply device 7 for supplying hydraulic oil (pressure oil) to the hydraulic motor 9 and the hydraulic cylinders 5 and 6 are provided.

Each of the plurality of traveling devices 2 includes a drive wheel 8 rotatably supported around the horizontal shaft core, and a hydraulic motor 9 built in a shaft support portion of the drive wheel 8. Each traveling device 2 can rotationally drive the drive wheels 8 separately by operating the hydraulic motor 9.

In this embodiment, when defining the front-rear direction of the vehicle body, it is defined along the vehicle body traveling direction, and when defining the left-right direction of the vehicle body, the left and right are defined in the state of being viewed in the vehicle traveling direction. That is, the direction indicated by the reference numeral (A) in FIG. 1 is the vehicle body front-rear direction, and the direction indicated by the reference numeral (B) in FIG. 2 is the vehicle body left-right direction.

The vehicle body 1 includes a rectangular frame-shaped support frame 10 that surrounds the entire circumference of the vehicle body 1 and supports the entire circumference. The hydraulic oil supply device 7 is housed and supported inside the vehicle body 1. As shown in FIG. 1, the hydraulic oil supply device 7 includes two hydraulic pumps 12 and 13 driven by an engine 11 mounted on a vehicle, a plurality of hydraulic cylinders 5 and a plurality of hydraulic pressures from the hydraulic pumps 12 and 13. A hydraulic control unit 14 for controlling the supply state of the hydraulic oil supplied to the motor 9 and a hydraulic oil tank (not shown) for storing the hydraulic oil are provided to supply and discharge the hydraulic oil or adjust the flow rate. ..

To add a description, as shown in FIG. 9, a first hydraulic pump 12 that supplies hydraulic oil to a plurality of hydraulic motors 9 and a second hydraulic pump 13 that supplies hydraulic oil to a plurality of hydraulic cylinders 5 and 6 are provided. I have. Both the first hydraulic pump 12 and the second hydraulic pump 13 are driven by the engine 11. Then, in the hydraulic control unit 14, the first hydraulic control unit (VU1) that controls the hydraulic oil supply state to each hydraulic motor so that the pressure oil from the first hydraulic pump 12 becomes an appropriate state according to the work situation. ) 15, and the second hydraulic control unit (VU2) 16 that controls the hydraulic oil supply state to each of the hydraulic cylinders 5 and 6 so that the pressure oil from the second hydraulic pump 13 becomes an appropriate state according to the work situation. Is provided.

The first hydraulic pressure control unit 15 is provided with four electromagnetically operated hydraulic control valves (not shown) that individually adjust the hydraulic pressure supply state for each of the four hydraulic motors 9. The second hydraulic control unit 16 is provided with eight electromagnetically operated hydraulic control valves (not shown) that individually adjust the hydraulic pressure supply state for each of the eight hydraulic cylinders 5 and 6.

Inside the vehicle body 1, a control device 17 for controlling the operation of the hydraulic oil supply device 7 is provided. Although the control operation of the control device 17 is not described in detail, it is based on the command information input by a manual input device (for example, a remote controller or the like) (not shown) or the command information set and stored in advance. The first hydraulic control unit 15 controls the supply state of hydraulic oil to the plurality of hydraulic motors 9, and the second hydraulic control unit 16 controls the supply state of hydraulic oil to the plurality of hydraulic cylinders 5 and 6. The postures of the plurality of refraction link mechanisms 4 can be changed separately by operating the hydraulic cylinders 5 and 6. Auxiliary wheels 3 are freely rotatable supported by intermediate refraction portions (see FIG. 4) of each of the plurality of refraction link mechanisms 4. As shown in FIGS. 1 and 2, the training wheels 3 are composed of wheels having substantially the same outer diameter as the drive wheels 8 of the traveling device 2.

Next, a support structure for supporting the traveling device 2 on the vehicle body 1 will be described.
Each of the four traveling devices 2 is supported by the refraction link mechanism 4 so as to be vertically movable with respect to the vehicle body 1. The refraction link mechanism 4 is supported by the vehicle body 1 so as to be reorientable around the vertical axis core by the turning mechanism 18.

The refraction link mechanism 4 is swingably supported by the support frame 10 around the vertical axis core Y via the swivel mechanism 18. The swivel mechanism 18 is connected to the support frame 10 and swings to support the refraction link mechanism 4 on the vehicle body side (see FIGS. 3 and 4) and the refraction link mechanism 4 to swivel. A hydraulic cylinder (hereinafter referred to as a swivel cylinder) 20 is provided.

As shown in FIGS. 3, 4, 5 and 6, the vehicle body side support portion 19 is provided with respect to a pair of upper and lower square tubular front-rear facing frame bodies 21 provided on the lateral side portion of the support frame 10. The connecting member 22 is fitted and engaged in a state of being sandwiched from the outside on the lateral side, and is detachably bolted to the connecting member 22, and the connecting member 22 is located on the outer side in the front-rear direction of the vehicle body. The inner side pivot bracket 24 located at the inner side portion of the connecting member 22 in the front-rear direction of the vehicle body, and the vertical rotation support shaft 25 supported by the outer side pivot bracket 23 are provided. The refraction link mechanism 4 is rotatably supported around the axis Y of the dynamic support shaft 25.

The refraction link mechanism 4 has a base end portion 26 supported by a vehicle body side support portion 19 rotatably around a vertical axis core Y in a state where the vertical position is fixed, and one end portion is a base end portion 26. The first link 27 is swingably supported around the horizontal axis X1 at the lower part of the above, and one end is swingably supported around the horizontal axis X2 at the other end of the first link 27 and the other end. Is provided with a second link 28 on which the traveling device 2 is supported. Therefore, the refraction link mechanism 4 is an articulated link mechanism having two joints.

To add an explanation, the base end portion 26 is provided in a rectangular frame shape in a plan view, and is rotatable around the vertical axis core Y via the rotary support shaft 25 at a portion deviated inward in the width direction of the vehicle body. It is supported by the outer side pivot bracket 23 of the vehicle body side support portion 19. One end of the swivel cylinder 20 is rotatably connected to the inner pivot bracket 24, and the other end is laterally displaced with respect to the rotary support shaft 25 at the base end 26. It is rotatably connected.

A support shaft 29 provided on one end side of the first link 27 is rotatably erected and supported over both left and right sides of the base end portion 26, and the first link 27 is a support shaft with respect to the lower portion of the base end portion 26. It is rotatably connected around the axis of 29.

As shown in FIG. 4, the first link 27 has a proximal end side arm portion 27b and an other end side arm portion 27a. A base end side arm portion 27b extending obliquely upward and outward is integrally formed at one end side of the first link 27. The other end side arm portion 27a extending diagonally upward and outward is integrally formed at the other end side portion of the first link 27.

As shown in FIG. 3, the second link 28 includes a pair of left and right strip-shaped plate bodies 28a and 28b, and is formed in a bifurcated shape in a plan view. A pair of plate bodies 28a and 28b are spaced apart from each other at the connection points of the second link 28 with respect to the first link 27. A connecting support shaft 35 for connecting to the first link 27 is rotatably supported in a region sandwiched between the pair of plate bodies 28a and 28b. The traveling device 2 is supported at the swinging side end portion of the second link 28 opposite to the connection portion with respect to the first link 27. As shown in FIG. 4, the swing-side end of the second link 28 is formed with an L-shaped extension 28A extending in a substantially L-shape in a direction away from the vehicle body 1, and the L-shaped extension 28A The traveling device 2 is supported at the end on the extension side.

Hydraulic cylinders 5 and 6 are provided corresponding to each of the plurality (4) refraction link mechanisms 4. As shown in FIGS. 1 and 4, the first hydraulic cylinder 5 capable of changing the swinging posture of the first link 27 with respect to the vehicle body 1 and the second link 28 capable of changing the swinging posture with respect to the first link 27. (Ii) A hydraulic cylinder 6 is provided. The first hydraulic cylinder 5 and the second hydraulic cylinder 6 are arranged in the vicinity of the first link 27, respectively.

The first link 27, the first hydraulic cylinder 5, and the second hydraulic cylinder 6 are arranged so as to be located between the pair of plate bodies 28a and 28b of the second link 28 in a plan view. As shown in FIGS. 3 and 4, the first hydraulic cylinder 5 is located inward in the vehicle body front-rear direction with respect to the first link 27, and is provided along the longitudinal direction of the first link 27. One end of the first hydraulic cylinder 5 is interlocked and connected to the lower part of the base end 26 via the arc-shaped first interlocking member 30.
One end of the first hydraulic cylinder 5 is interlocked and connected to the base end side portion of the first link 27 via another second interlocking member 31. Both side ends of the first interlocking member 30 and the second interlocking member 31 are pivotally connected so as to be relatively rotatable. The other end of the first hydraulic cylinder 5 is interlocked and connected to the other end arm portion 27a integrally formed with the first link 27.

The second hydraulic cylinder 6 is located on the opposite side of the first hydraulic cylinder 5, that is, on the outer side in the vehicle body front-rear direction with respect to the first link 27, and is provided so as to substantially follow the longitudinal direction of the first link 27. Has been done. One end of the second hydraulic cylinder 6 is interlocked and connected to the base end side arm portion 27b integrally formed on the base end side of the first link 27. The other end of the second hydraulic cylinder 6 is interlocked and connected to the arm portion 33 integrally formed at the base end side of the second link 28 via the third interlocking member 32. The other end of the second hydraulic cylinder 6 is also interlocked and connected to the swing end side of the first link 27 via another fourth interlocking member 34. Both side ends of the third interlocking member 32 and the fourth interlocking member 34 are pivotally connected so as to be relatively rotatable.

When the first hydraulic cylinder 5 is expanded and contracted while the operation of the second hydraulic cylinder 6 is stopped, the first link 27, the second link 28, and the traveling device 2 are integrally maintained while maintaining a constant relative posture. , Swings around the horizontal axis X1 of the pivotal connection with respect to the proximal end 26. When the second hydraulic cylinder 6 is expanded and contracted while the operation of the first hydraulic cylinder 5 is stopped, the second link 28 and the traveling device 2 are integrally formed while the posture of the first link 27 is maintained constant. It swings around the horizontal axis X2 at the connection point between the first link 27 and the second link 28.

As shown in FIG. 3, the connecting support shaft 35 that pivotally connects the first link 27 and the second link 28 is extended so as to project outward in the lateral width direction of the vehicle body from the second link 28. .. The training wheels 3 are rotatably supported at the extension protruding portion of the connecting support shaft 35. That is, the connecting support shaft 35 that pivotally connects the first link 27 and the second link 28 is configured to also serve as the rotating support shaft of the training wheels 3, and the configuration is simplified by also using the members. ing.

As shown in FIG. 3, one end of the swivel cylinder 20 is rotatably connected to the inner pivot bracket 24, and the other end is lateral to the rotary support shaft 25 at the base end 26. It is rotatably connected to a location that is misaligned in the direction.

As shown in FIGS. 7 and 8, the refraction link mechanism 4, the traveling device 2, the training wheels 3, and the hydraulic cylinders 5 and 6 are integrally rotated around the axis Y of the rotation support shaft 25. It is freely supported by the outer side pivot bracket 23. Then, by expanding and contracting the swivel cylinder 20, they are integrally rotated. The traveling device 2 can be turned by about 45 degrees in each of the left turning direction and the right turning direction from the straight traveling state facing the front-rear direction.

When the bolt connection of the connecting member 22 to the front-rear frame body 21 is released, the swivel mechanism 18, the refraction link mechanism 4, the traveling device 2, the auxiliary wheels 3, and the hydraulic cylinders 5 and 6 are integrally assembled. In this state, it can be removed from the vehicle body 1. Further, by connecting the connecting member 22 to the front-rear frame body 21 by bolts, the devices can be attached to the vehicle body 1 in a state of being integrally assembled.

The hydraulic oil is supplied from the hydraulic oil supply device 7 to the first hydraulic cylinder 5 and the second hydraulic cylinder 6 of each of the plurality of refraction link mechanisms 4. The hydraulic oil is supplied and discharged, and the first hydraulic cylinder 5 and the second hydraulic cylinder 6 can be expanded and contracted. The hydraulic oil supply device 7 is controlled by the control device 17.

Further, the rotation speed of the hydraulic motor 9, that is, the drive wheels 8 can be changed by adjusting the flow rate of the hydraulic oil supplied to the hydraulic motor 9. The hydraulic oil supply device 7 is controlled by the control device 17 based on the control information input manually or the control information set and stored in advance.

As shown in FIG. 1, this work vehicle is equipped with various sensors. Specifically, the first head side pressure sensor S1 provided in each first hydraulic cylinder 5, the first cap side (anti-head side) pressure sensor S2, and the second provided in each second hydraulic cylinder 6. A cap side pressure sensor S3 and a second head side (anti-cap side) pressure sensor S4 are provided. The first head side pressure sensor S1 detects the hydraulic pressure in the head side chamber of the first hydraulic cylinder 5. The first cap side pressure sensor S2 detects the hydraulic pressure in the cap side chamber of the first hydraulic cylinder 5. The second cap side pressure sensor S3 detects the hydraulic pressure in the cap side chamber of the second hydraulic cylinder 6. The second head side pressure sensor S4 detects the hydraulic pressure in the head side chamber of the second hydraulic cylinder 6. Although not shown, each of the hydraulic cylinders 5 and 6 is equipped with a stroke sensor capable of detecting the expansion / contraction stroke amount, and is configured to feed back the operating state to the control device 17.

The mounting positions of the pressure sensors S1, S2, S3, and S4 are not limited to the above positions. Each pressure sensor S1, S2, S3, S4 may be provided in the pipe between the valve mechanism and the corresponding cap side chamber or head side chamber, as long as it can detect (estimate) the hydraulic pressure of the corresponding cap side chamber or head side chamber. May be good.

Based on the detection results of these sensors, the force required to support the vehicle body 1 is calculated, and based on the results, the hydraulic oil is supplied to the first hydraulic cylinder 5 and the second hydraulic cylinder 6, respectively. Is controlled. Specifically, based on the detected value of the first head side pressure sensor S1 and the detected value of the first cap side pressure sensor S2, the first hydraulic pressure is obtained from the differential pressure between the cap side chamber and the head side chamber of the first hydraulic cylinder 5. The cylinder thrust of the cylinder 5 is calculated. Further, based on the detected value of the second cap side pressure sensor S3 and the detected value of the second head side pressure sensor S4, the cylinder thrust of the second hydraulic cylinder 6 is calculated in the same manner as the first hydraulic cylinder 5.

The vehicle body 1 is provided with an acceleration sensor S5 including, for example, a three-axis acceleration sensor. Based on the detection result of the acceleration sensor S5, the inclination of the vehicle body 1 in the front-rear and left-right directions is detected, and the posture of the vehicle body 1 is controlled based on the result. That is, the supply of hydraulic oil to the first hydraulic cylinder 5 and the second hydraulic cylinder 6 is controlled so that the posture of the vehicle body 1 becomes the target posture.

The traveling device 2 includes a rotation sensor S6 that detects the rotation speed of the drive wheels 8. Based on the rotation speed of the drive wheels 8 calculated by the rotation sensor S6, the supply of hydraulic oil to the hydraulic motor 9 is controlled so that the rotation speed of the drive wheels 8 becomes a target value.

As described above, the work vehicle of the present embodiment has a configuration in which the traveling device 2 is supported via the refraction link mechanism 4, and the posture of the refraction link mechanism 4 is changed by the hydraulic cylinders 5 and 6. Moreover, since the traveling drive is also performed by the hydraulic motor 9, it is not easily affected by moisture, fine dust, etc., and is suitable for agricultural work.

As an example of using a work vehicle having such a configuration, there are the following traveling modes.
<Running mode on flat ground>
When traveling on a flat ground, as shown in FIGS. 10, 11 and 12, it is possible to travel in any of a plurality of different traveling modes. That is, as shown in FIG. 10, a four-wheel traveling state in which all four traveling devices 2 (specifically, driving wheels 8) are in contact with the ground and all four auxiliary wheels 3 are raised from the ground is shown in FIG. As shown, the traveling device 2 (driving wheel 8) located on one side in the vehicle body front-rear direction floats, and the auxiliary wheel 3 corresponding to the traveling device 2 (driving wheel 8) touches the ground, and the other in the vehicle body front-rear direction. This is a two-wheel traveling state in which the traveling device 2 (driving wheel 8) located on the side is in contact with the ground and the auxiliary wheels 3 corresponding to the traveling device 2 (driving wheel 8) are surfaced.

As a two-wheel traveling state, the relationship between the traveling device 2 (driving wheel 8) and the auxiliary wheel 3 is opposite in the vehicle body front-rear direction, that is, as shown in FIG. 12, the traveling device located on one side in the vehicle body front-rear direction. 2 (driving wheel 8) touches the ground, and the auxiliary wheel 3 corresponding to the traveling device 2 (driving wheel 8) rises from the ground, and the traveling device 2 (driving wheel 8) located on the other side in the front-rear direction of the vehicle body rises. In addition, the auxiliary wheel 3 corresponding to the traveling device 2 (driving wheel 8) may come into contact with the ground.

In addition to the above-described traveling mode, as shown in FIG. 13, it is also possible to levitate all four sets of drive wheels 8 and switch to a free moving state for use. In this case, it is not possible to drive the vehicle, but it can be easily pushed and moved manually.

In addition to traveling on a flat surface as described above, this work vehicle can be used in the following forms as a unique form of use.

<Two-legged upright form>
The vehicle body 1 can be greatly tilted so that the traveling device 2 can be placed on a high place.
That is, as shown in FIG. 14, with the two sets of drive wheels 8 and the auxiliary wheels 3 on one side in the front-rear direction of the vehicle body all grounded, the two sets of drive wheels 8 and the auxiliary wheels on the other side in the front-rear direction of the vehicle body are all in contact with the ground. Using the refraction link mechanism 4 that supports 3, the vehicle body 1 is greatly tilted so that the other side rises. When the center of gravity position W of the vehicle body 1 is tilted until it is located within the ground contact width L of the two sets of drive wheels 8 and auxiliary wheels 3 on one side, the refraction link mechanism 4 on the other side is greatly extended and the drive wheels are extended. 8 can be placed on the ground at a high place.

In this two-legged upright form, in addition to the form of riding on a high place, as shown in FIGS. 15 and 16, it is possible to perform an operation of lifting another object. That is, as described above, the vehicle body 1 is greatly tilted with the two sets of traveling devices 2 on one side in the front-rear direction of the vehicle body and the training wheels 3 grounded, and the center of gravity position W of the vehicle body 1 is the ground contact width L. Tilt until it is located inside.
Further, when the floating traveling devices 2 on the left and right sides are swiveled so as to approach each other, the object M to be transported can be grasped and lifted.

<Slope running form>
As shown in FIG. 17, the postures of all four sets of the refraction link mechanisms 4 are changed to the extended postures in which the traveling device 2 is located outside the vehicle body front-rear direction outer end portion. With the traveling device 2 and the training wheels 3 all in contact with the ground, the first link 27 and the second link 28 are brought as close to the horizontal posture as possible to lower the height of the vehicle body 1 to a low position. In such a state, the vehicle runs while climbing up the slope. In this traveling mode, the ground contact width along the front-rear direction of the vehicle body is widened, and even on a slope with a large inclination, the vehicle can travel in a stable state without falling.

<Straddling running form>
As shown in FIG. 18, the four sets of refraction link mechanisms 4 are greatly extended to raise the vehicle body 1 from the ground plane. For example, the work can be performed with the vehicle body 1 positioned above the ridges while straddling the ridges. Even if the crop planted in the ridge grows, for example, chemical spraying or harvesting work can be performed from the upper side of the crop.

Although detailed description is omitted, when traveling in various forms as described above, the commanded contents are set based on the control information input by manual operation or the control information set and stored in advance. The control device 17 controls the operation of each of the hydraulic cylinders 5, 6 and 20 and each hydraulic motor 9 so as to have a corresponding form.

[Another reference embodiment]
In the above reference embodiment, both the first hydraulic pump 12 and the second hydraulic pump 13 are driven by the engine 11, but instead of this configuration, the following configuration may be used.

As shown in FIG. 19, the first hydraulic pump 12 may be driven by the engine 11 and the second hydraulic pump 13 may be driven by the electric motor 40. In this configuration, the pressure oil from the first hydraulic pump 12 is always supplied to the plurality of hydraulic motors 9, and the pressure oil from the second hydraulic pump 13 is always supplied to the plurality of hydraulic cylinders 5 and 6. Good. In this configuration, when the posture of the vehicle body is changed while the vehicle is stopped, the engine 11 can be stopped, which is advantageous in terms of noise reduction and fuel suppression.

[Embodiment]
Next, an embodiment of the present invention will be described. In this embodiment, the hydraulic circuit configuration is different from that of the reference embodiment, but the other configurations are the same. Therefore, the description of the same configuration as that of the reference embodiment will be omitted.
In the above reference embodiment, both the first hydraulic pump 12 and the second hydraulic pump 13 are driven by the engine 11. However, as shown in FIG. 20, the pressure oil from the first hydraulic pump 12 is subjected to a plurality of hydraulic pressures. The configuration may be such that the state of supplying the pressure oil from the second hydraulic pump 13 to the state of supplying the pressure oil from the second hydraulic pump 13 to the plurality of hydraulic motors 9 can be switched. That is, the hydraulic control unit 14 is provided with a flow path switching mechanism 41 as an oil passage switching means in the pressure oil supply path from the first hydraulic pump 12 and the pressure oil supply path from the second hydraulic pump 13, and the first hydraulic pump. The configuration is such that the pressure oil from the 12 is supplied to the plurality of hydraulic motors 9 and the pressure oil from the second hydraulic pump 13 is supplied to the plurality of hydraulic motors 9.

In this configuration, for example, when traveling on a rough road with severe unevenness, when traveling for a long time, when traveling at high speed, etc., the first hydraulic pump 12 driven by the engine 11 By supplying pressure oil to a plurality of hydraulic motors 9, stable running can be performed. On the other hand, for example, when the position of the vehicle body 1 is to be changed slightly, when the work vehicle is loaded or unloaded on the driving vehicle or the like, or when the vehicle travels at an extremely low speed, it is driven by the electric motor 40. By supplying the pressure oil from the second hydraulic pump 13 to the plurality of hydraulic motors 9, there is an advantage that fine adjustment can be easily performed.

[Another Embodiment]
( 1 ) In the above embodiment, the refraction link mechanism 4 as the vehicle body support portion is configured by an articulated link mechanism having two links 27 and 28, but the present invention is not limited to this configuration, and three or more links are formed. It may be an articulated link mechanism configured to be pivotally connected. Further, the vehicle body support portion may support the traveling device separately with respect to the vehicle body so that the height and position can be freely changed. Instead of the articulated link mechanism, for example, one swing link is supported. It can be implemented in various forms such as a configuration in which the drive wheels are supported by a hydraulic cylinder so as to be vertically movable with respect to the vehicle body.

( 2 ) In the above embodiment, in the first hydraulic cylinder 5 , the cylinder tube side is pivotally connected to the connected portion (base end portion 26) on the vehicle body side, and the piston rod side is connected to the connected portion (arm) on the first link side. The configuration is such that the first hydraulic cylinder 5 is pivotally connected to the portion 33), but instead of this configuration, the cylinder tube side is pivotally connected to the connected portion (arm portion 33) on the first link side, and the piston. The rod side may be pivotally connected to the connected portion (base end portion 26) on the vehicle body side.

( 3 ) In the above embodiment, the traveling device 2 is configured to include one drive wheel 8, but instead of this configuration, the traveling device 2 is a crawler traveling device in which a crawler belt is wound around a plurality of wheels. It may be configured to include.

( 4 ) In the above embodiment, the traveling devices 2 are provided in pairs on the front and rear sides of the vehicle body 1, but the traveling devices 2 are provided in three or five or more traveling devices 2. It may be provided.

The present invention can be applied to a work vehicle suitable for traveling on an uneven road surface.

1 Vehicle body 2 Traveling device 4 Vehicle body support (refractive link mechanism)
5, 6 Hydraulic cylinder 9 Hydraulic motor 11 Engine 12 First hydraulic pump 13 Second hydraulic pump 40 Electric motor 41 Oil passage switching means

Claims (2)

With the vehicle body
With multiple traveling devices to drive
A plurality of vehicle body support portions that support the plurality of traveling devices separately with respect to the vehicle body so that the height position can be changed.
A plurality of hydraulic motors for driving the plurality of traveling devices separately,
A plurality of hydraulic cylinders capable of changing and operating a plurality of the vehicle body support portions,
A first hydraulic pump that supplies pressure oil to the plurality of hydraulic motors,
A second hydraulic pump, which supplies pressure oil to multiple hydraulic cylinders , is provided.
The first hydraulic pump is driven by an engine, and the second hydraulic pump is driven by an electric motor.
An oil passage switching means capable of switching between a state in which pressure oil from the first hydraulic pump is supplied to the plurality of hydraulic motors and a state in which pressure oil from the second hydraulic pump is supplied to the plurality of hydraulic motors. Work vehicle equipped . The vehicle body support portion is composed of an articulated link mechanism in which a plurality of links are pivotally connected so as to have at least two or more joints, and the traveling device is movably supported on the vehicle body. The work vehicle according to claim 1.

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