JP2018167691A - Work vehicle - Google Patents

Abstract

To solve a problem in that, in a work environment where fine dusts, moisture and the like are present, a work vehicle that can maintain, with a compact support structure, an appropriate position even in a rough work ground has been demanded.SOLUTION: A plurality of articulated mechanisms 10 supporting a plurality of running devices 2 on a vehicle body such that the plurality of running devices can be freely raised or lowered separately comprises: a first hydraulic cylinder 29 having a first link 25 and a second link 26 and capable of changing a swinging position of the first link 25; and a second hydraulic cylinder 30 capable of changing a swinging position of the second link 26. The hydraulic cylinders 29, 30 are collectively arranged near the first link 25. One-end side of the first hydraulic cylinder 29 is pivotally coupled via two coupling members 31, 32 and the other-end side of the second hydraulic cylinder 30 is pivotally coupled via two coupling members 34, 36.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a work vehicle suitable for traveling on a road surface with many irregularities.

  Conventionally, a plurality of traveling wheels provided at four corners of a vehicle main body are respectively supported by the vehicle main body via a refractive link mechanism that includes two joints and is configured to bend and extend, and is incorporated in the refractive link mechanism. In some cases, the electric motor can be bent and stretched by the driving force of the electric motor (see, for example, Patent Document 1).

JP-A-9-142347

  The above-described conventional configuration makes it possible to travel while maintaining the main body in an appropriate posture while bending and stretching the refractive link mechanism even when the traveling road surface is uneven. Therefore, it is conceivable to apply such a configuration to an agricultural work vehicle that travels in a work place with uneven road surfaces. However, the support structure in the above-described conventional configuration has been difficult to adopt for agricultural work vehicles.

  In other words, in agricultural work vehicles, there may be a lot of fine dust, such as dirt generated during traveling and floating dust generated from crops during harvesting, in the vicinity of the work vehicle. Moisture may be deposited due to dew or morning dew. In the above conventional configuration, the link mechanism for supporting the traveling wheel is driven to bend and stretch by the built-in electric motor. Therefore, if fine dust or moisture enters the inside, the electric motor, the speed reduction mechanism, etc. There is a risk that problems will occur early.

  In order to avoid such disadvantages, it is conceivable to perform the drive operation of the link mechanism using a hydraulic cylinder in a working environment where there are many fine dusts and moisture. When the refraction link mechanism is driven and operated using a hydraulic cylinder in this way, one end of the hydraulic cylinder is supported on a strong position on the vehicle body side, for example, a support frame, and the other end is operated on the refraction link mechanism. The structure connected to (link member etc.) can be considered easily.

  In such a configuration, the installation space for installing the hydraulic cylinder becomes large, and there is a disadvantage that the support structure for greatly raising and lowering the traveling device with respect to the vehicle body is increased.

  Therefore, there has been a demand for a work vehicle capable of maintaining an appropriate posture with a compact support structure even in a work environment having a lot of irregularities and having a lot of fine dust and moisture.

The characteristic configuration of the work vehicle according to the present invention is:
A vehicle body,
A plurality of traveling devices for driving, and
A plurality of refraction link mechanisms for supporting the plurality of traveling devices on the vehicle main body so as to be movable up and down separately;
A drive mechanism capable of changing the posture of each of the plurality of refractive link mechanisms,
The refraction link mechanism has a first link whose one end is pivotally connected to the vehicle body so as to be swingable around a horizontal axis, and one end is swingable around the horizontal axis to the other end of the first link. And a second link that is pivotally connected to the other end and that supports the traveling device on the other end side,
The drive mechanism includes a first hydraulic cylinder capable of changing a swinging posture of the first link relative to the vehicle body, and a second hydraulic cylinder capable of changing a swinging posture of the second link relative to the first link. Have
Each of the first hydraulic cylinder and the second hydraulic cylinder is arranged in the vicinity of the first link,
One end of the first hydraulic cylinder is pivotally connected to a support member on the vehicle body side via a first interlocking member, and is pivotally connected to one end of the first link via a second interlocking member. The other end side of the first hydraulic cylinder is pivotally connected to the other end side of the first link, the one end side of the second hydraulic cylinder is pivotally connected to the one end side of the first link, and the second The other end of the hydraulic cylinder is pivotally connected to one end of the second link via a third interlocking member, and is pivotally connected to the other end of the first link via a fourth interlocking member. There is in point.

  According to the present invention, the refractive link mechanism is operated to change the posture by the two hydraulic cylinders. The hydraulic cylinder is generally waterproof and dustproof. For this reason, even if moisture or dust adheres to the surface, it can be prevented from entering the inside, so that it is less likely to cause a malfunction due to an adverse effect. As a result, the posture changing operation can be performed satisfactorily even in a work environment where fine dust or moisture may enter.

  Since each of the first hydraulic cylinder and the second hydraulic cylinder is concentrated in the vicinity of the first link, it can be installed compactly without taking up a large space.

  Then, one end of the first hydraulic cylinder is pivotally connected to the first link via the second interlocking member. For example, if the first hydraulic cylinder and the first link are directly linked and connected, the first hydraulic cylinder interferes with the swing support shaft of the first link and restricts the swing movement amount of the first link. There is a risk of receiving. However, in the above configuration, the expansion / contraction operation can be allowed in a state where the swing support shaft is detoured by the second interlocking member.

  One end side of the first hydraulic cylinder is also pivotally connected to the support member on the vehicle body side via the first interlocking member, and the position is regulated by the first interlocking member and the second interlocking member, so Operation does not become unstable. Such a cylinder operating state is the same for the second hydraulic cylinder provided with the third interlocking member and the fourth interlocking member.

  As a result, while the hydraulic cylinder can be arranged in a compact manner, the swing operation amount of the first link and the second link for the operation of the hydraulic cylinder is increased, and the height of the traveling device with respect to the vehicle body is increased. It can be changed, and it is possible to maintain an appropriate posture even in a work place with many irregularities.

  Therefore, in a work environment where a lot of fine dust, moisture and the like exist, a compact support structure makes it possible to maintain an appropriate posture even in a work place with many irregularities.

  In the present invention, there are a plurality of turning mechanisms for supporting each of the plurality of refractive link mechanisms on the vehicle body so that the direction of the plurality of refractive link mechanisms can be changed around a longitudinal axis when the driving mechanism and the traveling device are integrally provided. It is suitable if it is provided.

  According to this configuration, each of the plurality of refractive link mechanisms can change its direction around the longitudinal axis while integrally including the drive mechanism and the traveling device. Even if the direction of the refraction link mechanism is changed, the relative position to the drive mechanism and the traveling device is the same, so the refraction link mechanism can be bent and extended at any turning position to change the height of the traveling device. Can do.

  Therefore, even when the ground is uneven, it is possible to get over well when turning.

  In the present invention, it is preferable that the turning mechanism is detachably attached to the vehicle body in a state in which the turning mechanism is integrally provided with the driving mechanism.

  According to this configuration, the turning mechanism can be detached from the vehicle main body with the drive mechanism and the traveling device integrally provided. For example, when the turning mechanism is mounted on a truck and transported, the turning mechanism is easily mounted and loaded on the loading platform. It becomes possible to do. Also, when a problem occurs, only one drive mechanism can be easily replaced.

1 is an overall side view of a work vehicle. 1 is an overall plan view of a work vehicle. It is a top view of a refractive link mechanism. It is a side view of a refractive link mechanism. It is a front view which shows the attachment state of the refractive link mechanism in the removed state. It is a front view which shows the attachment state of the refractive 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 turning state by a turning mechanism. It is explanatory drawing of a four-wheel drive state. It is explanatory drawing of a two-wheel drive state. It is explanatory drawing of a two-wheel drive state. It is a side view of a free movement state. It is a side view of a step overstep. It is a top view of an article conveyance state. It is a side view of an article conveyance state. It is a side view of a slope running state. It is a front view of a straddling running state.

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

  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, a plurality of (specifically, four) traveling devices 2, and a plurality of traveling devices 2. A plurality of idler wheels 3 provided corresponding to each, a refraction link mechanism 10 as a vehicle body support part that supports a plurality of traveling devices 2 on the vehicle body 1 so that the position of each of the traveling devices 2 can be changed individually, and a refraction link mechanism 10. A hydraulic drive type drive mechanism 5 serving as a changeable drive operation unit and a hydraulic oil supply device 6 for supplying hydraulic oil to the drive mechanism 5 are provided.

  Each of the plurality of traveling devices 2 includes a wheel 7 that is rotatably supported around a horizontal axis, and a hydraulic motor 9 that is built in a shaft support 8 of the wheel 7. Each traveling device 2 can rotate the wheels 7 individually 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-right direction is defined in a state viewed from the aircraft body traveling direction. That is, the direction indicated by reference numeral (A) in FIG. 1 is the vehicle body longitudinal direction, and the direction indicated by reference numeral (B) in FIG.

  The drive mechanism 5 can change the postures of the plurality of refractive link mechanisms 10 individually. The idler wheel 3 is supported on the intermediate refraction part 11 (see FIG. 4) of each of the plurality of refraction link mechanisms 10 so as to be freely rotatable. One traveling device 2 and one idler wheel 3 corresponding to the traveling device 2 constitute one set of traveling operation unit 12, and one set of traveling operation unit 12 is postured by one refraction link mechanism 10. Supported to change. A total of four traveling operation parts 12 are provided on each of the front and rear sides of the vehicle main body 1, each pair of left and right. Therefore, each of the refraction link mechanism 10, the traveling device 2, and the idler wheel 3 is provided on each of the front and rear sides of the vehicle body 1.

  The vehicle body 1 includes a rectangular frame-shaped support frame 13 that surrounds the entire circumference of the vehicle body 1 and supports the whole. The hydraulic oil supply device 6 is housed and supported inside the vehicle body 1. Although not described in detail, the hydraulic oil supply device 6 is driven by an engine mounted on the vehicle and is supplied to the drive mechanism 5 from a hydraulic pump that feeds hydraulic oil toward the drive mechanism 5. A plurality of hydraulic control valves, hydraulic oil tanks and the like for controlling the hydraulic oil are provided, and supply and discharge of hydraulic oil to the drive mechanism 5 and adjustment of the flow rate are performed.

  Inside the vehicle body 1, a control device 15 that controls the operation of the hydraulic oil supply device 6 is provided. Although the control operation of the control device 15 is not described in detail, the drive mechanism 5 and the hydraulic motor 9 are based on control information input by a manual input device (not shown) or control information that is set and stored in advance. The supply state of hydraulic oil to the is controlled.

Next, a support structure for supporting the traveling device 2 on the vehicle body 1 will be described.
A plurality (specifically four) of the traveling devices 2 are supported by the vehicle main body 1 via the refractive link mechanism 10 so as to be movable up and down individually. The refraction link mechanism 10 is supported by the vehicle body 1 by a turning mechanism 16 so that the direction of the refraction link mechanism 10 can be changed around the longitudinal axis.

  The refraction link mechanism 10 is supported by the support frame 13 so as to be swingable around the vertical axis Y through a turning mechanism 16. The turning mechanism 16 is connected to the support frame 13 and supports the refraction link mechanism 10 so that the refraction link mechanism 10 can swing, and a turn for turning the refraction link mechanism 10. And a hydraulic cylinder 18 (hereinafter referred to as a swivel cylinder).

  In other words, as shown in FIGS. 3, 4, 5, and 6, the vehicle body side support portion 17 is opposed to a pair of upper and lower rectangular tube-shaped front and rear facing frames 19 provided at the lateral side portions of the support frame 13. The connecting member 20 is engaged and engaged in a state of being pinched from the outside on the lateral side, and is detachably bolted, and the outer side pivot bracket 21 located at the outer side of the connecting member 20 in the longitudinal direction of the vehicle body. And an inward pivot bracket 22 positioned at an inner side position of the connecting member 20 in the longitudinal direction of the vehicle body, and a vertical pivot support shaft 23 supported by the outer pivot bracket 21. The refractive link mechanism 10 is supported so as to be rotatable around the axis Y of the movable support shaft 23.

  The refracting link mechanism 10 has a base end portion 24 supported by the vehicle body side support portion 17 in a state where the vertical position is fixed and is rotatable around the longitudinal axis Y, and one end portion is a base end portion 24. The first link 25 is supported at the lower part of the first link 25 so as to be swingable around the horizontal axis X1, and the other end is supported at the other end of the first link 25 so as to be swingable around the horizontal axis X2. And a second link 26 on which the traveling device 2 is supported.

  In other words, the base end portion 24 is provided in a rectangular frame shape in plan view, and is rotatable around the vertical axis Y through the rotation support shaft 23 at a position biased inward in the lateral direction of the vehicle body. Further, it is supported by the outer side pivot support bracket 21 of the vehicle body side support portion 17. The revolving cylinder 18 has one end portion rotatably connected to the inner side pivot support bracket 22 and the other end portion at a position displaced laterally with respect to the rotation support shaft 23 in the base end portion 24. It is pivotally connected.

  A support shaft 27 provided on one end side of the first link 25 is rotatably supported across the left and right side portions of the base end portion 24, and the first link 25 is supported on the lower portion of the base end portion 24. It is connected so as to be rotatable around the axis of 27.

  As shown in FIG. 4, the first link 25 has a base end side arm portion 25 b and another end side arm portion 25 a. A base end side arm portion 25b extending obliquely upward and outward is integrally formed at one end side portion of the first link 25. At the other end side portion of the first link 25, an other end side arm portion 25a extending obliquely upward and outward is integrally formed.

  As shown in FIG. 3, the second link 26 includes a pair of left and right belt-like plate bodies 26 a and 26 b and is formed in a bifurcated shape in plan view. A pair of plate bodies 26a, 26b are spaced apart from each other at the connection position of the second link 26 to the first link 25. A connection support shaft 28 for connecting to the first link 25 is rotatably supported in a region sandwiched between the pair of plate bodies 26a and 26b. The traveling device 2 is supported on the swing side end portion of the second link 26 opposite to the connection portion with respect to the first link 25. As shown in FIG. 4, the swing side end of the second link 26 is formed with an L-shaped extending portion 26 </ b> A extending in a substantially L shape in a direction away from the vehicle body 1, and the L-shaped extending portion 26 </ b> A The traveling device 2 is supported on the extended side end.

  A drive mechanism 5 is provided corresponding to each of a plurality (four) of the refraction link mechanisms 10. As shown in FIGS. 1 and 4, the drive mechanism 5 includes a first hydraulic cylinder 29 capable of changing a swinging posture of the first link 25 with respect to the vehicle body 1 and a swing of the second link 26 with respect to the first link 25. A second hydraulic cylinder 30 capable of changing the posture is provided. The first hydraulic cylinder 29 and the second hydraulic cylinder 30 are collectively arranged in the vicinity of the first link 25, respectively.

  The first link 25, the first hydraulic cylinder 29, and the second hydraulic cylinder 30 are disposed in a state of being positioned between the pair of plate bodies 26a, 26b of the second link 26 in plan view. As shown in FIGS. 3 and 4, the first hydraulic cylinder 29 is located on the inner side in the vehicle longitudinal direction with respect to the first link 25 and is provided along the longitudinal direction of the first link 25. One end of the first hydraulic cylinder 29 is interlocked to the lower portion of the base end portion 24 via an arc-shaped first interlocking member 31. One end of the first hydraulic cylinder 29 is interlocked and connected to the base end side portion of the first link 25 via another second interlocking member 32. The first interlocking member 31 and the second interlocking member 32 are pivotally connected so that both end portions can be relatively rotated. The other end portion of the first hydraulic cylinder 29 is interlocked and connected to the other end side arm portion 25 a formed integrally with the first link 25.

  The second hydraulic cylinder 30 is provided on the opposite side of the first hydraulic cylinder 29, that is, on the outer side in the vehicle body front-rear direction with respect to the first link 25 and substantially along the longitudinal direction of the first link 25. It has been. One end portion of the second hydraulic cylinder 30 is interlocked and connected to a base end side arm portion 25 b formed integrally with the base end side of the first link 25. The other end of the second hydraulic cylinder 30 is interlocked and connected to an arm portion 35 that is integrally formed at one end of the second link 26 via a third interlocking member 34. The other end of the second hydraulic cylinder 30 is also linked to the swing end side portion of the first link 25 via another fourth linkage member 36. The third interlocking member 34 and the fourth interlocking member 36 are pivotally connected so that both end portions can be relatively rotated.

  When the first hydraulic cylinder 29 is expanded and contracted while the operation of the second hydraulic cylinder 30 is stopped, each of the first link 25, the second link 26, and the traveling device 2 is integrally integrated with the relative posture maintained constant. Oscillates around the horizontal axis X1 of the pivot connection point with respect to the base end portion 24. When the second hydraulic cylinder 30 is expanded and contracted in a state where the operation of the first hydraulic cylinder 29 is stopped, the second link 26 and the traveling device 2 are integrated with each other while the posture of the first link 25 is maintained constant. It swings around the horizontal axis X2 where the first link 25 and the second link 26 are connected.

  The idler wheel 3 is supported on the intermediate refraction part 11 of each of the plurality (four) of refraction link mechanisms 10 so as to be freely rotatable. As shown in FIGS. 1 and 2, the idler wheel 3 is constituted by a wheel having substantially the same outer diameter as the wheel 7 of the traveling device 2. As shown in FIG. 3, a connecting support shaft 28 that pivotally connects the first link 25 and the second link 26 is extended so as to protrude outward in the lateral direction of the vehicle body from the second link 26. . The idler wheel 3 is rotatably supported at an extended projecting portion of the connecting support shaft 28. That is, the connection support shaft 28 that pivotally connects the first link 25 and the second link 26 is configured to also serve as the rotation support shaft of the idler wheel 3, and simplification of the configuration can be achieved by using the members. I am trying.

  As shown in FIG. 3, the turning cylinder 18 has one end portion rotatably connected to the inward pivot bracket 22, and the other end portion lateral to the rotation support shaft 23 in the base end portion 24. It is rotatably connected to a location that is displaced in the direction.

  As shown in FIGS. 7 and 8, each of the refractive link mechanism 10, the traveling device 2, the idler wheel 3, and the drive mechanism 5 is integrally rotatable around the axis Y of the rotation support shaft 23. The outer pivot bracket 21 is supported on the outer side. Then, by extending and retracting the turning cylinder 18, they are integrally rotated. The traveling device 2 can be turned about 45 degrees in each of the left turning direction and the right turning direction from a straight traveling state in which the traveling device 2 faces in the front-rear direction.

  When the bolt connection of the connecting member 20 to the front-rear frame body 19 is released, each of the turning mechanism 16, the refraction link mechanism 10, the traveling device 2, the idler wheel 3, and the drive mechanism 5 is assembled integrally. In the state, it can be removed from the vehicle body 1. Further, by connecting the connecting member 20 to the front-rear frame body 19 with bolts, the above-mentioned devices can be attached to the vehicle body 1 in an integrally assembled state.

  The hydraulic oil is supplied from the hydraulic oil supply device 6 to the first hydraulic cylinder 29 and the second hydraulic cylinder 30 of each of the plurality of refraction link mechanisms 10. The hydraulic oil is supplied and discharged by the hydraulic control valve, so that the first hydraulic cylinder 29 and the second hydraulic cylinder 30 can be expanded and contracted. The hydraulic control valve is controlled by the control device 15.

  Further, the hydraulic oil flow rate is adjusted by the hydraulic control valve corresponding to the hydraulic motor 9, so that the rotational speed of the hydraulic motor 9, that is, the wheel 7 can be changed. The hydraulic control valve is controlled by the control device 15 based on control information input by manual operation, control information set and stored in advance, or the like.

  As shown in FIG. 1, the work vehicle includes various sensors. Specifically, the first cap side pressure sensor S1 and the first head side (anti-cap side) pressure sensor S2 provided in each first hydraulic cylinder 29, and the second cap side pressure sensor S2 provided in each second hydraulic cylinder 30. A cap side pressure sensor S3 and a second head side (non-cap side) pressure sensor S4 are provided. The first cap side pressure sensor S <b> 1 detects the oil pressure in the cap side chamber of the first hydraulic cylinder 29. The first head side pressure sensor S <b> 2 detects the hydraulic pressure in the head side chamber of the first hydraulic cylinder 29. The second cap side pressure sensor S <b> 3 detects the oil pressure in the cap side chamber of the second hydraulic cylinder 30. The second head side pressure sensor S4 detects the hydraulic pressure in the head side chamber of the second hydraulic cylinder 30. Although not shown, each of the hydraulic cylinders 18, 29, and 30 is provided with a stroke sensor that can detect the amount of expansion / contraction stroke, and is configured to feed back the operation state to the control device 15. .

  In addition, the attachment position of each pressure sensor S1, S2, S3, S4 is not restricted to the above-mentioned position. Each pressure sensor S1, S2, S3, S4 only needs to be able to detect (estimate) the hydraulic pressure of the corresponding cap side chamber or head side chamber, and is provided in a pipe between the corresponding cap side chamber or head side chamber from the valve mechanism. Also 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 29 and the second hydraulic cylinder 30, respectively. Is controlled. Specifically, based on the detected value of the first cap side pressure sensor S1 and the detected value of the first head side pressure sensor S2, the first hydraulic pressure is calculated from the differential pressure between the cap side chamber and the head side chamber of the first hydraulic cylinder 29. The cylinder thrust of the cylinder 29 is calculated. Further, based on the detection value of the second cap side pressure sensor S3 and the detection value of the second head side pressure sensor S4, the cylinder thrust of the second hydraulic cylinder 30 is calculated in the same manner as the first hydraulic cylinder 29.

  The vehicle body 1 is provided with an acceleration sensor S5 composed of, for example, a triaxial acceleration sensor. Based on the detection result of the acceleration sensor S5, the front / rear / left / right inclination of the vehicle body 1 is detected, and the attitude of the vehicle body 1 is controlled based on the result. That is, the supply of hydraulic oil to the first hydraulic cylinder 29 and the second hydraulic cylinder 30 is controlled so that the posture of the vehicle body 1 becomes a target posture.

  The traveling device 2 includes a rotation sensor S6 that detects the rotation speed of the wheel 7. Based on the rotation speed of the wheel 7 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 wheel 7 becomes a target value.

  As described above, the working vehicle of the present embodiment is configured to support the traveling device 2 via the refraction link mechanism 10, and the hydraulic cylinders 29 and 30 serving as the hydraulic drive type drive mechanism 5 are used for the refraction link mechanism 10. Since the configuration is such that the posture is changed and the traveling drive is also performed by a hydraulic motor, it is less affected by moisture, fine dust, etc., and is suitable for farm work.

Examples of use of the work vehicle having such a configuration include the following travel modes.
<Driving form on flat ground>
When traveling on a flat ground, as shown in FIGS. 9, 10, and 11, the vehicle can travel in any of a plurality of different travel modes. That is, as shown in FIG. 9, a four-wheel running state in which all four traveling devices 2 (specifically, wheels 7) are grounded and all four idle wheels 3 are lifted from the ground, and FIG. As shown, the traveling device 2 (wheel 7) located on one side in the longitudinal direction of the vehicle body floats and the idler wheel 3 corresponding to the traveling device 2 (wheel 7) contacts the ground, and the other side in the longitudinal direction of the vehicle body. This is a two-wheel traveling state in which the traveling device 2 (wheel 7) located in the ground is grounded and the idler wheel 3 corresponding to the traveling device 2 (wheel 7) is levitated.

  As a two-wheel running state, a state in which the relationship between the running device 2 (wheel 7) and the idler wheel 3 is opposite in the longitudinal direction of the vehicle body, that is, as shown in FIG. 2 (wheel 7) is grounded and the idler wheel 3 corresponding to the traveling device 2 (wheel 7) floats up from the ground, and the traveling device 2 (wheel 7) located on the other side in the vehicle longitudinal direction floats up and There is also a state where the idler wheel 3 corresponding to the traveling device 2 (wheel 7) is grounded.

  In other words, the refraction link mechanism 10 includes a traveling state in which the traveling device 2 (wheel 7) is grounded and the idler wheel 3 corresponding to the traveling device 2 floats from the ground in each of the four traveling operation units 12. It is configured to be able to be switched to a free movement state in which the wheel 3 is grounded and the traveling device 2 (wheel 7) corresponding thereto floats up from the ground.

  In the four-wheel running state, all the four sets of the traveling operation units 12 are set to the traveling state, and in the two-wheeled traveling state, two sets of the traveling operations on one side in the vehicle body front-rear direction among the four traveling operation units 12. The part 12 is set to the traveling state, and the two sets of traveling operation parts 12 on the opposite side are set to the free movement state.

  In addition to the four-wheel traveling state and the two-wheel traveling state as described above, for example, three traveling operation units 12 out of four traveling operation units 12 are in a traveling state, and another one traveling operation is performed. It is also possible to switch to a partial running state in which the part 12 is in a free movement state. Accordingly, it is possible to perform an operation such as extending one traveling operation unit 12 to the upper side of the step, for example, while stably grounding with the three traveling operation units 12. In addition, as a part of the traveling state, three traveling operation units 12 out of the four traveling operation units 12 are in a free movement state, and the other one traveling operation unit 12 is switched to the traveling state. Is possible.

  In short, the drive mechanism 5 is in an all traveling state in which all of the four traveling operating units 12 are in the traveling state, and at least one of the four traveling operating units 12 is in the traveling state, and the remaining ones. Can be switched to a partially traveling state in which the vehicle is in a free movement state.

  In addition to the travel mode as described above, as shown in FIG. 12, all four travel operation parts 12 can be switched to the free movement state and used. In this case, the vehicle cannot be driven, but can be manually pushed and moved easily.

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

<Two-leg upright configuration>
The vehicle main body 1 can be greatly inclined and the traveling device 2 can be placed at a high place.
That is, as shown in FIG. 13, in a state where the traveling devices 2 and the idler wheels 3 in the two sets of traveling operation units 12 on one side in the vehicle longitudinal direction are all grounded, Using the refractive link mechanism 10 that supports the traveling operation unit 12, the vehicle body 1 is largely inclined so that the other side is raised. When the center of gravity position W of the vehicle body 1 is tilted until it is located within the ground contact width L by the two sets of travel operation parts 12 on one side, the refractive link mechanism 10 that supports the two sets of travel operation parts 12 on the other side is provided. The travel device 2 can be put on the ground at a high place by extending greatly.

  In this biped upright configuration, as shown in FIGS. 14 and 15, it is possible to perform an operation of lifting another object in addition to the configuration of climbing up to a high place. That is, as described above, the vehicle body 1 is greatly inclined with the traveling device 2 and the idler wheels 3 in the two sets of traveling operation units 12 on one side in the longitudinal direction of the vehicle body in contact with each other. The position W is inclined until it is located within the ground contact width L by the two sets of traveling operation units 12 on one side. Furthermore, the two sets of travel operation units 12 on the other side in the longitudinal direction of the vehicle body are turned so that the travel operation units 12 on the left and right sides approach each other. The respective traveling devices 2 in the two sets of traveling operation units 12 on the other side in the longitudinal direction of the vehicle body grip and lift the object M to be transported. While holding the object M, the two traveling operation units 12 on one side in the longitudinal direction of the vehicle body can travel and move while maintaining the posture of the vehicle body 1, and the object M can be conveyed.

<Slope driving mode>
As shown in FIG. 16, with respect to all four sets of traveling operation units 12, the position of the refraction link mechanism 10 is set such that the traveling device 2 and the idler wheel 3 are positioned on the outer side in the vehicle longitudinal direction with respect to the outer end in the vehicle longitudinal direction. Change to the extended posture. In a state where the traveling device 2 and the idler wheel 3 are all in contact with each other, the first link 25 and the second link 26 are brought as close to the horizontal posture as possible to lower the height of the vehicle body 1 to a low position. In this state, run while climbing the slope. In this traveling mode, the ground contact width along the longitudinal direction of the vehicle body is wide, and even a slope with a large slope can travel in a stable state without falling down.

<Variation over steps>
In a state where the traveling device 2 and the idler wheel 3 in the three traveling operation units 12 of the four sets of traveling operation units 12 are all grounded and the vehicle body 1 is stably grounded and supported on the ground, The refraction link mechanism 10 that supports the remaining set of travel operation units 12 is greatly extended, and the travel device 2 is placed on the upper surface of the step as shown in FIG. 13, for example. And it becomes possible to get over a level | step difference by moving the driving | running | working action | operation part 12 one by one, moving on the upper surface of a level | step difference, expanding / contracting the refractive link mechanism 10 in the driving | running | working action parts 12 of each group. Although FIG. 13 shows a case where the level difference is high, the vehicle main body 1 can ride up if the level difference is low.

<Stride travel mode>
As shown in FIG. 17, the refractive link mechanism 10 is greatly extended and the vehicle body 1 is greatly raised from the ground contact surface for all of the four sets of travel operation units 12. For example, the work can be performed in a state where the vehicle main body 1 is positioned above the heel while straddling the heel. Even if the crop planted in the pod grows, for example, chemical spraying or harvesting work can be performed from above the crop.

  Although detailed explanation is omitted, when traveling in various forms as described above, the commanded contents are based on control information input by manual operation or control information set and stored in advance. The control device 15 controls the operations of the hydraulic cylinders 18, 29, 30 and the hydraulic motors 9 so as to correspond to each other.

[Another embodiment]
(1) In the above embodiment, the traveling device 2 is driven by the hydraulic motor 9, but instead of this configuration, for example, the power of the engine mounted on the vehicle is a mechanical transmission mechanism such as a chain transmission mechanism. The structure supplied to the wheel 7 via may be sufficient.

(2) In the above embodiment, the traveling device 2 includes one wheel 7. However, instead of this configuration, the traveling device 2 includes a crawler traveling device in which a crawler belt is wound around a plurality of ring bodies. It is good also as a structure provided.

(3) In the above embodiment, the travel operation unit 12 is provided with a pair of left and right sides at the front and rear side portions of the vehicle body 1. However, the configuration in which three travel operation units 12 are provided, or the travel operation unit 12 is provided. The structure provided with five or more may be sufficient.

(4) In the above embodiment, the turning mechanism 16 is provided with the turning hydraulic cylinder 18 capable of turning the entire refraction link mechanism 10. However, the turning operation may be performed by an electric motor or a hydraulic motor. .

  The present invention can be applied to a work vehicle suitable for traveling on a road surface with many irregularities.

DESCRIPTION OF SYMBOLS 1 Vehicle main body 2 Traveling device 5 Drive mechanism 10 Refractive link mechanism 16 Turning mechanism 25 1st link 26 2nd link 29 1st hydraulic cylinder 30 2nd hydraulic cylinder 31 1st interlocking member 32 2nd interlocking member 34 3rd interlocking member 36 Fourth interlocking member

Claims (3)

A vehicle body,
A plurality of traveling devices for driving, and
A plurality of refraction link mechanisms for supporting the plurality of traveling devices on the vehicle main body so as to be movable up and down separately;
A drive mechanism capable of changing the posture of each of the plurality of refractive link mechanisms,
The refraction link mechanism has a first link whose one end is pivotally connected to the vehicle body so as to be swingable around a horizontal axis, and one end is swingable around the horizontal axis to the other end of the first link. And a second link that is pivotally connected to the other end and that supports the traveling device on the other end side,
The drive mechanism includes a first hydraulic cylinder capable of changing a swinging posture of the first link relative to the vehicle body, and a second hydraulic cylinder capable of changing a swinging posture of the second link relative to the first link. Have
Each of the first hydraulic cylinder and the second hydraulic cylinder is arranged in the vicinity of the first link,
One end of the first hydraulic cylinder is pivotally connected to a support member on the vehicle body side via a first interlocking member, and is pivotally connected to one end of the first link via a second interlocking member. The other end side of the first hydraulic cylinder is pivotally connected to the other end side of the first link, the one end side of the second hydraulic cylinder is pivotally connected to the one end side of the first link, and the second The other end of the hydraulic cylinder is pivotally connected to one end of the second link via a third interlocking member, and is pivotally connected to the other end of the first link via a fourth interlocking member. Working vehicle.   A plurality of turning mechanisms are provided that support each of the plurality of refracting link mechanisms on the vehicle main body so that the direction of the refracting link mechanism can be changed around the longitudinal axis when the driving mechanism and the traveling device are integrally provided. Item 4. The work vehicle according to Item 1.   The work vehicle according to claim 2, wherein the turning mechanism is detachably attached to the vehicle main body in a state in which the driving mechanism and the traveling device are integrally provided.

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