JP2017048522A - Work machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a work machine that prevents a shift to a loading state when an operator gripped and pushed down a part other than an unloading lever.SOLUTION: A work machine includes: a steering box supported rotatably and pivotally on a support bracket beside an operator seat, with a first horizontal shaft in between; a control lever provided on the steering box; an unloading lever supported swingably on the steering box; and a cam body supported rotatably and pivotally on the steering box with a second horizontal shaft in between, and having a cam groove. The support blanket includes a first guide pin located on one side of the cam groove when the unloading lever is in a lowered position, and on the other side of the cam groove when the unloading lever is in a raised position. The unloading lever includes a second guide pin located on one side of a first guide groove when in the lowered position, and on the other side of the first guide groove when in the raised position. The first guide groove includes a first engaging part engaging the second guide pin on one side of the first guide groove, and a second engaging part engaging the second guide pin on the other side of the first guide groove.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a work machine such as a backhoe, a skid loader, or a truck loader used for construction work or civil engineering work.

As a conventional technique, a technique disclosed in Patent Document 1 is known.
A working machine disclosed in Patent Document 1 includes a fuselage, a control platform provided on the control console, a driver seat provided on the control console, a control device provided on the side of the driver seat, and a control console. And a support bracket fixed to the frame. The control device is pivotally supported by the support bracket so as to be rotatable via a horizontal axis, an operation lever provided in the control box, and is pivotally supported by the control box via a horizontal axis. It has a rotation detection means comprising a cam body, an unload lever fixed to the cam body, and a limit switch. The rotation detection means detects when the unload lever is lifted (when the limit switch is turned on) and enters the unload state where the operation by the control device is impossible, and when the unload lever is pushed down (limit) When the switch is turned off), a load state (unload release state) in which an operation by the control device is possible is set.

JP 2009-235799 A

  However, in the disclosed technique of Patent Document 1, in the state where the unload lever is pulled up (unload state), even if the driver grips and pushes down a part other than the unload lever (for example, the operation lever), the load state Can be migrated to. Therefore, even when the driver inadvertently pushes down the operation lever, a load state in which the operation by the control device can be performed.

  The present invention has been made to solve the above-described problems of the prior art, and in a state in which the unload lever is pulled up, the driver moves a part other than the unload lever (for example, an operation lever). An object of the present invention is to provide a working machine capable of preventing a shift to a loaded state when gripped and pushed down.

In order to solve the above problems, the present invention has taken the following technical means.
According to a first aspect of the present invention, there is provided a work machine including a driver's seat, a working device having a hydraulic actuator, a support bracket provided on a side of the driver's seat and having a first guide groove, A control box pivotally supported through a shaft and having an operation lever, and is supported by the control box so as to be swingable and whether or not hydraulic oil is supplied to the hydraulic actuator can be controlled by the swing. An unload lever and a cam body pivotally supported by the control box via a second horizontal axis and having a cam groove, and the support bracket responds to the swing of the unload lever. When the position of the cam groove is changed, and the unload lever is in the pushed down position, the cam groove is positioned at one side of the cam groove and at the lifted position, A first guide pin positioned in the direction, the unload lever changes position in the first guide groove in response to swinging of the unload lever, and the unload lever is in a pushed-down position. Sometimes it has a second guide pin that is located on one side of the first guide groove and on the other side of the first guide groove when in the raised position, and the first guide groove has the second guide pin in contact with the second guide pin. A first locking portion that locks at one side of the one guide groove; and a second locking portion that locks the second guide pin at the other side of the first guide groove.

In the working machine according to a second aspect of the present invention, the unload lever is pivotally supported so as to be rotatable between an upper first position and a lower second position with respect to the cam body, and the second guide. The pin is detached from the second locking portion when the unload lever is rotated from the first position to the second position.
In the working machine according to a third aspect of the present invention, the cam body has a second guide groove, and the unload lever is located in one of the second guide grooves when the unload lever is in the first position. And a third guide pin located on the other side of the second guide groove when in the second position.

  A work machine according to a fourth aspect of the present invention includes a biasing member that applies a biasing force that rotates the unload lever upward to hold the unload lever at the first position.

  According to the working machine of the present invention, when the unload lever is in the lifting position, the second guide pin of the unload lever is locked at the second locking portion of the first guide groove, and the unload lever is in the lifting position. Therefore, the first guide pin remains in a state where it is located on the other side of the cam groove. Therefore, the rotation of the cam body relative to the support bracket is prevented, and the rotation of the control box pivotally supported by the cam body is prevented. As a result, the control box cannot be rotated unless the unload lever is operated to disengage the second guide pin from the second locking portion, and the parts other than the unload lever (such as the operation lever) are pushed down. In this case, the transition to the load state is prevented.

When the unload lever is in the pushed down position (load state), the second guide pin of the unload lever is locked to the first locking portion of the first guide groove. Therefore, it is possible to prevent the unload lever from being resonated due to vibration during traveling, and the unload lever from jumping up due to the resonance and becoming an unloaded state.
The unload lever is pivotally supported between the upper first position and the lower second position with respect to the cam body, and the second guide pin has the unload lever from the first position to the first position. When it is rotated to the second position, it is detached from the second locking portion. Thereby, by rotating the unload lever from the first position to the second position, the second guide pin can be disengaged from the second locking portion, and the transition to the loaded state can be enabled.

  The cam body has a second guide groove, and the unload lever is located in one of the second guide grooves when the unload lever is in the first position, and the second guide groove when in the second position. The third guide pin is located on the other side of the first guide pin. Thereby, the rotation range of the unload lever with respect to the cam body can be restricted to a certain range (range from the first position to the second position) by the second guide groove. Therefore, it is possible to easily perform an operation of canceling the unload state by the unload lever.

  In addition, since it has a biasing member that applies a biasing force that pivots upward to hold the unload lever in the first position, the unload lever can be moved in the state where the unload lever is not operated. It can be securely held in one position. Therefore, it is possible to reliably prevent the unload lever from inadvertently descending and shifting to the loaded state.

It is a front view which shows the control part structure of a working machine. It is a top view which shows the control part structure of a working machine. It is a left view which shows the control part structure of a working machine. It is a principal part right view of a left steering device. It is a left perspective view (a part is omitted) of the left steering device. It is a top view of a left steering device. It is a front view of a left steering device. It is a left perspective view of a left steering device. It is a left view which shows the internal structure of a left steering device. It is a right perspective view of a left steering device. It is a right view which shows the internal structure of a left steering device. It is a left view which shows the structure of an unload lever and a cam body. It is a left view which shows the state (lock state) which made the unload lever into the raising position. It is a right view which shows the operation | movement process (1st step) of the left control apparatus accompanying the push-down operation of an unload lever. It is a right view which shows the operation | movement process (2nd step) of the left control apparatus accompanying the push-down operation of an unload lever. It is a right view which shows the operation | movement process (3rd step) of the left control apparatus accompanying the push-down operation of an unload lever. It is a right view which shows the operation | movement process (4th step) of the left control apparatus accompanying the push-down operation of an unload lever. It is a top view of a working machine. It is a side view of a working machine.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIG. 18 and FIG. 19, reference numeral 1 denotes a backhoe exemplified as a work machine (turning work machine).
The work machine 1 includes a body (vehicle body) 2, a traveling device 3, and a work device 4.
A cabin 20 is mounted on the body 2. Hereinafter, the front side (left side in FIG. 19) of the driver seated in the driver's seat 8 of the cabin 20 is front, the rear side (right side in FIG. 19) is rearward, and the left side (front side in FIG. 19) of the driver. The left side and the right side of the driver (the back side in FIG. 19) will be described as the right side. Further, the horizontal direction 7 (see FIG. 18), which is a direction orthogonal to the front-rear direction, will be described as the body width direction.

The airframe 2 has a swivel base 6 supported on the frame of the traveling device 3. The swivel base 6 is supported through a bearing so as to be turnable to the left and right around a vertical axis. A work device 4 is attached to the right front portion of the swivel base 6. In FIG. 18, the working device 4 and the cabin 20 are omitted.
The cabin 20 is mounted on the left part on the swivel base 6. A driver's seat 8 is provided inside the cabin 20. As shown in FIGS. 1 and 2, a left steering device 22 is provided on the left side of the driver's seat 8. A right steering device 23 is provided to the right of the driver's seat 8. A passenger entrance 20a is provided on the left side of the cabin 20 and on the left side of the driver's seat 8. A door 20A is provided at the entrance 20a.

  An engine room is provided at the rear of the swivel base 6. An engine E, a hydraulic pump, an air cleaner, and the like are arranged in the engine room. The front side of the engine room is partitioned from the driver's seat 8 by a partition wall 11A. The rear side of the engine room is covered with a rear bonnet 10A. The left side of the engine room is covered with a left cover body 10B.

A tank room is provided on the right side of the turntable 6. In the tank room, a hydraulic oil tank T, a control valve Q, a radiator, and the like are arranged. The left side of the tank room is partitioned from the driver's seat 8 by a partition wall 11B. The upper side, front side, and right side of the tank room are covered with the right cover body 10C.
The working device 4 is attached to the front portion of the swivel base 6 via a support bracket 12 and a swing bracket 13. The support bracket 12 is fixed to the front portion of the swivel base 6. The swing bracket 13 is supported by the support bracket 12 so as to be swingable left and right around the vertical axis. The swing bracket 13 is swung left and right by a hydraulic swing cylinder. A counterweight W is attached to the rear part of the swivel base 6 in order to balance the weight with the working device 4.

The traveling device 3 is a crawler type traveling device, and is provided on the right side and the lower left side of the body 2. The traveling device 3 is driven by a hydraulic traveling motor. A dozer 9 is provided at the front of the traveling device 3. The dozer 9 is swung up and down by a dozer cylinder comprising a hydraulic cylinder.
The work device 4 includes a boom 14, an arm 15, and a work tool 16. The work device 4 includes a boom cylinder 17, an arm cylinder 18, and a work tool cylinder 19 as drive mechanisms (hydraulic actuators) for the boom 14 and the like. The boom cylinder 17, the arm cylinder 18 and the work tool cylinder 19 are constituted by double-acting hydraulic cylinders.

The boom 14 is supported by the swing bracket 13 so as to be swingable in the vertical direction. The arm 15 is supported on the tip side of the boom 14 so that the base side can swing. The bucket as the work tool 16 is attached to the distal end side of the arm 15 so that a squeeze / dump operation is possible.
A control unit S is provided on the swivel base 6. As shown in FIG. 18, the control section S is partitioned from the engine room by the partition wall 11A, and is partitioned from the tank room by the partition wall 11B. A driver's seat 8 is provided in the control unit S. As shown in FIGS. 1 and 3, the driver's seat 8 includes a seat 8 </ b> A serving as a seat surface and a seat base 8 </ b> B provided below the seat 8 </ b> A. As shown in FIG. 18, a left traveling operation lever SL and a right traveling operation lever SR are arranged in front of the driver seat 8. By operating the left traveling operation lever SL and the right traveling operation lever SR, the left and right crawler traveling bodies 4 can be operated separately or simultaneously. Betals are arranged on the left and right feet of the driver's seat 8. A cockpit 21 is provided below the driver's seat 8.

As shown in FIGS. 1, 2, etc., a left steering device 22 and a right steering device 23 are mounted on the control table 21. The left steering device 22 is provided on the left side of the driver's seat 8. The right steering device 23 is provided on the right side of the driver's seat 8.
As shown in FIG. 1, the control table 21 has a substantially flat upper surface portion 21A, a left leg portion 21L, and a right leg portion 21R. A storage space 21B having an open front surface is formed below the upper surface portion 21A and between the left leg portion 21L and the right leg portion 21R. The storage space 21B stores an air conditioner K1, an electric box K2, and the like. The electrical box K2 contains electrical parts for replacement (fuses, relays, etc.).

21 A of upper surface parts have mounting part 21a, 21b, 21c. The driver's seat 8 is mounted on the mounting portion 21a. The left steering device 22 is mounted on the mounting portion 21b. A right steering device 23 is mounted on the mounting portion 21c.
The control table 21 is formed of, for example, two metal plates and includes a first member P1 and a second member P2. The first member P1 has mounting portions 21a and 21b on the upper surface portion 21A and a left leg portion 21L. The second member P2 has a placement portion 21c on the upper surface portion 21A and a right leg portion 21R. The first member P1 and the second member P2 are connected via bolts or the like.

  As shown in FIGS. 1 and 2, the right steering device 23 has a steering bracket 45. The control bracket 45 is provided with a control valve (first valve) 46 and a work tool operation valve (second valve) 47. The steering bracket 45 has a vertical wall 45A and a mounting portion 45B. The vertical wall 45 </ b> A is erected on the cockpit 21. The mounting part 45B is fixed to the upper part of the mounting part 21c of the control table 21 with a bolt.

  The right steering valve 46 can be operated by a right operation lever 48. The work tool operation valve 47 can be operated by a work operation lever 49. The right steering valve 46 is a boom / bucket pilot valve, and the control valve for the boom cylinder 17 and the bucket cylinder 19 can be controlled by the right operation lever 48. The work tool operation valve 47 is a pilot valve for driving the dozer 9, and the work operation lever 49 can control the control valve for the dozer cylinder.

As shown in FIGS. 3 to 11, the left steering device 22 includes a steering box 26, a cam body 33, and an unload lever 31.
The steering box 26 is pivotally supported by the first horizontal shaft 27 with respect to the support bracket 25.
As shown in FIGS. 5 and 10, the support bracket 25 has a mounting portion 25 </ b> A arranged in a horizontal direction and a support portion 25 </ b> B raised from the mounting portion 25 </ b> A. The mounting portion 25A is fixed to the mounting portion 21b of the control table 21.

  As shown in FIGS. 5 to 7 and the like, the control box 26 includes a left plate member 26a, a right plate member 26b, a mounting plate 26c, and a bearing plate 26d, and is formed in a box shape. The left plate member 26 a forms the left side wall of the control box 26. For convenience of explanation, in some drawings, the left plate member 26a is indicated by a virtual line (two-dot chain line). As shown in FIG. 5 and the like, the right plate member 26b is bent in an L shape in plan view, and forms a right side wall and a back wall of the control box 26. The rear part of the left plate member 26a and the back wall of the right plate member 26b are fixed. The mounting plate 26c is fixed so as to connect the front portion of the left plate member 26a and the front portion of the right plate member 26b. The interval between the left plate member 26a and the right plate member 26b is narrower than the width of the mounting plate 26c. The bearing plate 26d is fixed to the inner surface (front surface) of the back wall of the left plate member 26b. The left surface of the bearing plate 26d faces the inner surface (right side surface) of the left plate material 26a. The right surface of the bearing plate 26d faces the inner surface (left side surface) of the right plate member 26b.

  A mounting portion 26 </ b> A for the left control valve 28 is formed on the mounting plate 26 c of the control box 26. The left steering valve 28 is mounted on the mounting portion 26A. The mounting portion 26A has a substantially semicircular opening 26B with the right front portion opened. Thereby, the left control valve 28 can be mounted on the opening 26B of the mounting portion 26A from the front right side on the driver's seat 8 side. The left control valve 28 is a pilot valve for turning and arm operation, and is operated by the left operation lever 30. The left operation lever 30 is attached to the upper part of the mounting portion 26 </ b> A of the control box 26.

  As shown in FIGS. 5, 10, 11, and the like, the support portion 25 </ b> B of the support bracket 25 is provided with a first horizontal shaft 27 and a first guide groove 24. The first horizontal axis 27 extends in the horizontal direction (machine width direction). The first guide groove 24 is provided above the first horizontal shaft 27. As shown in FIGS. 10 and 11, the first guide groove 24 includes a front groove 24A, an intermediate groove 24B, and a rear groove 24C. The front groove 24A extends upward and slightly forward from the front portion of the support portion 25B. The intermediate groove 24B extends rearward and slightly upward from the upper end of the front groove 24A. The rear groove 24C extends downward and slightly rearward from the rear end of the intermediate groove 24B. The lower end of the rear groove 24C is located slightly above the lower end of the front groove 24A.

A second guide pin 44 described later is inserted into the first guide groove 24. The front groove 24A functions as a first locking portion that locks the second guide pin 44 on one side (front side) of the first guide groove 24. The rear groove 24B functions as a second locking portion that locks the second guide pin 44 on the other side (rear side) of the first guide groove 24.
A boss portion 26 </ b> C is provided at the lower rear portion of the control box 26. The boss portion 26C extends in the lateral direction (machine width direction) so as to connect the left plate member 26a and the bearing plate 26d. The boss portion 26 </ b> C is rotatably fitted on the outer periphery of the first horizontal shaft 27. Thereby, the control box 26 is rotatably supported with the first horizontal shaft 27 as a fulcrum (around the first horizontal shaft 27).

  A second horizontal shaft 32 extending in the horizontal direction (machine width direction) is provided at the rear portion of the control box 26. The second horizontal axis 32 is located behind the first horizontal axis 27 and behind the first guide groove 24. A base portion (rear portion) of the cam body 33 is pivotally supported at the rear portion of the control box 26 via a second horizontal shaft 32. The cam body 33 extends forward and downward from the second horizontal shaft 32. A base portion (a lever base portion 31B described later) of the unload lever 31 is pivotally supported via a third horizontal shaft 36 at a lower portion (a pivot supporting portion 51 described later) of the cam body 33.

The unload lever 31 is swingably supported by the control box 26 via the cam body 33. The unload lever 31 can be operated by supplying the hydraulic oil to the hydraulic actuator of the work device 4 by the swing.
The cam body 33 has a cam groove 34 formed from one side (rear part) to the other side (front part). As shown in FIG. 5 and the like, the support portion 25B of the support bracket 25 is provided with a first guide pin 35 having an axis extending in the body width direction. The first guide pin 35 is located in front of the first horizontal shaft 27 and at an intermediate height between the second horizontal shaft 32 and the first horizontal shaft 27. Further, as shown in FIG. 11 and the like, the first guide pin 35 is located between the front groove 24A and the rear groove 24C of the first guide groove 24 and below the intermediate groove 24B. The first guide pin 35 is inserted into the cam groove 34 via a cam follower. In FIG. 5, the cam body 33 and the like are omitted.

  The cam groove 34 has a first cam groove 34A and a second cam groove 34B. The first cam groove 34 </ b> A is formed on one side (rear part) of the cam body 33. The second cam groove 34 </ b> B is formed on the other side (front portion) of the cam body 33. Specifically, the second cam groove 34 </ b> B extends forward from the front end portion of the first cam groove 34. The first cam groove 34 </ b> A is formed in an arc shape centered on the axis of the second horizontal shaft 32. The second cam groove 34B is formed to have an arc shape centered on the axis of the first horizontal shaft 27 when the first guide pin 35 is in the second cam groove 34B (see FIGS. 13 to 15). Has been. The cam groove 34 is formed to have a length that allows the control box 26 to rotate around a required angle, for example, about 50 °.

  As shown in FIGS. 9, 11, and 13 to 17, when the unload lever 31 is pulled up, the cam body 33 has the second horizontal shaft 32 as a fulcrum (around the second horizontal shaft 32), and one (upward) ). As the cam body 33 rotates, the position of the first guide pin 35 changes within the cam groove 34. Specifically, the cam groove 34 moves relatively from one (rear) to the other (front). More specifically, it moves relatively from the first cam groove 34A to the second cam groove 34B. That is, when the unload lever 31 is in the pushed down position (see FIG. 9), the first guide pin 35 is located in the first cam groove 34A on one side (rear side) of the cam groove 34 and is in the raised position ( 13) is located in the second cam groove 34B on the other (front) side of the cam groove. The movement of the first guide pin 35 will be described in detail later.

  As shown in FIGS. 8 and 9, a stay 37 having a substantially L shape in a side view is fixed to the upper surface of the rear portion (base portion) of the cam body 33. A return spring 38 as an urging member is interposed between the upper portion of the stay 37 and the mounting plate 26c of the control box 26. The upper portion of the stay 37 can come into contact with a stopper 54 (see FIG. 8) provided on the right plate member 26a. The unload lever 31 is urged by the return spring 38 in the push-down direction (counterclockwise direction in FIG. 9). A locking plate 53 that locks one end of a tension spring 50 as an urging member described later is fixed to the front portion of the stay 37.

As shown in FIG. 12, the cam body 33 has two through holes penetrating from one surface to the other surface. Of the two through holes, the rear through hole constitutes a pivot portion 51 on which a third horizontal shaft 36, which will be described later, is pivotally supported. The front through hole constitutes a second guide groove 52 that guides the movement of the third guide pin 40 described later.
As shown in FIG. 12, the second guide groove 52 is composed of a long hole provided in front of the pivotal support portion 51. The second guide groove 52 is formed in a substantially elliptical shape that is long in the vertical direction, and has an upper first position 52A and a lower second position 52B. A third guide pin 40 described later is inserted into the second guide groove 52.

As shown in FIG. 9, FIG. 12, etc., the unload lever 31 has a lever body 31A and a lever base 31B.
The lever main body 31 </ b> A is a part that is gripped when the driver operates the unload lever 31. As shown in FIG. 12, the rear end portion of the lever main body 31A is fixed to the front portion of the lever base portion 31B. As shown in FIGS. 9 and 11, the lever main body 31 </ b> A extends from the front portion of the lever base portion 31 </ b> B toward the front upper side of the control box 26.

The lever base 31B is formed of a plate-like member, and is arranged with one surface facing the right side (the support portion 25B side of the support bracket 25) and the other surface facing the left side (the cam body 33 side). Has been. That is, the lever base portion 31B is disposed between the support portion 25B of the support bracket 25 and the cam body 33 in the body width direction.
As shown in FIGS. 5 and 12, the lever base 31 </ b> B has a third horizontal shaft 36, a second guide pin 44, and a third guide pin 40.

The third horizontal shaft 36 is provided at the lower rear portion of the lever base 31B and protrudes toward the left (cam body 33 side). The third horizontal shaft 36 is located in front of the first horizontal shaft 27 and below the cam groove 34. The third horizontal axis 36 is located behind the third guide pin 40. The third horizontal axis 36 is a bolt in this embodiment.
The second guide pin 44 is provided at the upper rear portion of the lever base portion 31B and protrudes toward the right side (the support portion 25B side). The second guide pin 44 is provided above the third horizontal shaft 36. The protruding end (right end) of the second guide pin 44 is inserted into the first guide groove 24 and can move in the first guide groove 24 from the front groove 24A to the rear groove 24C. When the second guide pin 44 is positioned in the front groove (first locking portion) 24A of the first guide groove 24, the second guide pin 44 is locked in the front groove 24A, and the rear groove (second locking portion) 24C. When positioned, it is locked in the rear groove 24C.

The third guide pin 40 is provided at the front lower portion of the lever base 31B and protrudes toward the left (cam body 33 side). The third guide pin 40 is provided below and in front of the second guide pin 44. The 3rd guide pin 40 consists of a stepped volt | bolt in this embodiment.
As shown in FIG. 12, a concave notch 31b that is notched forward is formed at the rear of the lever base 31B. By forming the notch 31b, it is possible to prevent the first guide pin 35 from interfering with the lever base 31B when it moves along the cam groove 34.

As shown in FIG. 12 and the like, the lever base portion 31B is provided with a locking portion 31C for locking one end portion of the biasing member (tensile spring) 50. The locking portion 31C extends upward from the front upper portion of the lever base portion 31B.
As shown in FIG. 9, FIG. 12, and the like, the pivotal support portion 51 is positioned in front of the first guide pin 35, below the second guide pin 44, and behind the third guide pin 40. The unload lever 31 (the lever main body 31A and the lever base portion 31B) is rotatable with respect to the cam body 33 with the pivot portion 51 (the third horizontal shaft 36) as a fulcrum.

As shown in FIGS. 8, 12, etc., the second guide groove 52 is inserted with a shaft portion of a bolt constituting the third guide pin 40. The outer diameter of the head portion of the bolt constituting the third guide pin 40 is larger than the inner diameter of the second guide groove 52, and the head portion is located on the outer surface (left surface) of the cam body 33 on the left outside the second guide groove 52. ).
The third guide pin 40 has one of the second guide grooves 52 (first position 52A) when the unload lever 31 (the lever main body 31A and the lever base 31B) is rotated downward with the third horizontal shaft 36 as a fulcrum. ) To the other (second position 52B), and when rotated upward, moves from the other (second position 52B) to one (first position 52A). In other words, the third guide pin 40 has one of the second guide grooves 52 (first position 52A) when the unload lever 31 is in the upward rotation position (first position) with the third horizontal shaft 36 as a fulcrum. The second guide groove 52 is located on the other side (second position 52B) when in the downward rotation position (second position).

That is, the rotation range around the third horizontal shaft 36 of the unload lever 31 is the upper limit position when the third guide pin 40 is at the first position 52A, and the third guide pin 40 is at the second position 52B. At some point, it is the lower limit position. In other words, the rotation range of the unload lever 31 around the third horizontal axis 36 is restricted by the second guide groove 52.
As shown in FIGS. 9 and 12, a tension spring 50 as an urging member is interposed between the locking portion 31 </ b> C of the lever base portion 31 </ b> B and the locking plate 53. The tension spring 50 biases the unload lever 31 in a direction in which the unload lever 31 is rotated upward with the third horizontal shaft 36 as a fulcrum. The unload lever 31 is rotated upward by the urging force of the tension spring 50 with the third horizontal shaft 36 as a fulcrum, and this rotation is performed by the third guide pin 40 at the first position 52A of the second guide groove 52. It stops when it reaches. When the unload lever 31 is rotated downward against the urging force of the tension spring 50 with the third horizontal shaft 36 as a fulcrum, the third guide pin 40 moves from the first position 52A to the second position 52B.

  As shown in FIGS. 8 and 9 and the like, a rotation detection device 55 including a limit switch is provided on the bearing plate 26d of the control box 26. The switch piece at the tip of the rotation detection device 55 is engaged with the stay 37. The rotation detection device 55 is connected to the electronic control units of the left steering device 22 and the right steering device 23. The rotation detection device 55 operates an unload valve provided in the hydraulic circuit of each of the control devices 22 and 23 by being turned off from on.

When the unload lever 31 is pulled up, the cam body 33 rotates upward with the second horizontal shaft 32 as a fulcrum, and the stay 37 moves (rotates) together with the cam body 33. As the stay 37 moves, the switch piece of the rotation detection device 55 protrudes. As a result, the unloading lever 31 is lifted (unloaded), and the turning / arm and boom / bucket operation by the left steering attachment 22 and the right steering device 23 becomes impossible.

  As shown in FIGS. 8 to 11, a gas cylinder (gas spring) 39 as an urging member is provided between the support portion 25 </ b> B of the support bracket 25 and the control box 26. The gas cylinder 39 connects a pin 39a projecting from the front lower portion of the support portion 25B and a pin 39b projecting from an upper position of the control box 26. The gas cylinder 39 has an urging force in the extending direction, and assists in turning the left steering device 22 upward. Headed pins are used as the pins 39a and 39b. Thereby, securing of the mounting strength of the gas cylinder 39 and facilitation of disassembly and assembly are achieved.

  As shown in FIGS. 6, 10, 11, etc., the first contact mechanism 41 is provided on the support portion 25 </ b> B of the support bracket 25. The first contact mechanism 41 holds the left steering device 22 in a use position (see FIGS. 8 to 11) described later. The first contact mechanism 41 includes a mounting plate 41A fixed to the upper portion of the support portion 25B, and a first contact member 41B attached to the mounting plate 41A. The first contact member 41B contacts the first contact plate 70 fixed to the right plate member 26b of the control box 26 when the left steering device 22 is in the use position.

  As shown in FIGS. 8 to 11 and the like, a second contact mechanism 42 is provided on the mounting portion 25 </ b> A of the support bracket 25. The second contact mechanism 42 holds the left steering device 22 in an upward rotation position (avoidance position) (see FIG. 13) described later. The second contact mechanism 42 includes an attachment plate 42A fixed to the rear portion of the attachment portion 25A, and a second contact member 42B attached to the attachment plate 42A. The second contact member 42B contacts the second contact plate 56 fixed to the left plate member 26a of the control box 26 when the left control device 22 is in an upward rotation position (see FIG. 13) described later.

As shown in FIGS. 6 and 10, a guide member 43 is provided on the surface (right side surface) of the support bracket 25 on the driver's seat 8 side. The guide member 43 guides the hose connected to the left steering valve 28. The guide member 43 protrudes toward the driver's seat 8 from the mounting portion 25A of the support bracket 25.
The first horizontal shaft 27, the cam body 33, the unload lever 31, the return spring 38, the rotation detection device 55, the first contact mechanism 41, the second contact mechanism 42, and the like constitute the rotation mechanism 29. ing. When the left steering device 22 is rotated upward (withdrawn) by the turning mechanism 29, the entrance 20a on the left front side of the driver's seat 8 (that is, the front side of the left steering device 22) is widely secured. It is avoided that the left steering device 22 prevents the driver from getting on and off.

Hereinafter, the operation of the left steering device 22 accompanying the swing operation of the unload lever 31 will be described in detail. First, the state in which the unload lever 31 is in the pushed down position and the state in the raised position will be described, respectively, and then the operation of the left steering device 22 associated with the push down operation of the unload lever 31 will be described. In FIGS. 13 to 17, for the sake of simplicity, the gas cylinder 39 and the tension spring 50 are shown by a one-dot chain line only in the central axis. In addition, illustration of members unnecessary for description is partially omitted.
<The unload lever is in the pushed down position>
First, a state where the unload lever 31 is in the pushed down position will be described.

  8 to 11 show a state in which the unload lever 31 is in the pushed down position. In the left steering device 22, the states shown in FIGS. 8 to 11 are used positions (normal work positions) when working with the work machine 1. In this use position, the first abutment mechanism 41 restricts the downward rotation of the control box 26 around the first horizontal axis 27, and the left control device 22 is held in the use position. Specifically, when the first contact member 41 </ b> B contacts the first contact plate 70, the left steering device 22 is held at the use position.

As shown in FIGS. 8 and 9, in the use position, the first guide pin 35 is located at the base end (rear end) of the first cam groove 34A. As shown in FIGS. 10 and 11, the second guide pin 44 is locked to the front groove (first locking portion) 24 </ b> A of the first guide groove 24. The unload lever 31 is restricted from rotating downward (the counterclockwise direction in FIG. 9 and the clockwise direction in FIG. 11) by the first locking portion 24A and the stopper 54.

In this use position, the rotation detection device 55 is on, and the upward rotation of the unload lever 31 is not detected. That is, the unload lever 31 is in the unload release position. In this state, by operating the left operation lever 30 for the turning / arm, the turning of the turntable 6 and the raising / lowering of the arm 15 can be activated, and the operation by the right steering device 23 for the boom / bucket. Is enabled.
<The unload lever is in the raised position>
Next, a state where the unload lever 31 is in the lifted position will be described.

FIG. 13 shows a state where the unload lever 31 is in the lifted position. In the left steering device 22, the state shown in FIG. 13 is the upward rotation position (avoidance position). The left steering device 22 is held in the upward rotation position by the second contact member 42B of the second contact mechanism 42 coming into contact with the second contact plate 56 fixed to the left plate member 26a.
At this upward rotation position, the rotation detection device 55 is turned off, and the unload state by the unload lever 31 is detected. That is, the unload lever 31 is in the unload position. In this state, even if the left operation lever 30 for the turn / arm is operated, the turntable 6 and the arm 15 are disabled. Further, even if the right steering device 23 for the boom / bucket is operated, the boom 14 and the bucket 16 are disabled.

The unload lever 31 is urged by the urging force of the tension spring 50 in a direction of rotating upward with the third horizontal shaft 36 as a fulcrum. Therefore, the third guide pin 40 provided on the lever base 31 </ b> B of the unload lever 31 is held at the first position 52 </ b> A above the second guide groove 52.
The first guide pin 35 is located near the front end of the second cam groove 34B. The second guide pin 44 is locked to the rear groove (second locking portion) 25 </ b> C of the first guide groove 24. Since the second guide pin 44 is provided on the lever base 31B of the unload lever 31, it cannot be detached from the rear groove (second locking portion) 25C unless the unload lever 31 is operated. Therefore, the control box 26 cannot be rotated downward without holding the unload lever 31 (locked state). As a result, the driver is prevented from depressing a portion other than the unload lever 31 (the left operation lever 30 or the like) to enter the unload release state (load state).

<Operation of the left control device when the unload lever is pushed down>
<First stage>
In order to release the locked state from the state shown in FIG. 13, the driver slightly pushes down the unload lever 31 against the urging force of the tension spring 50. Specifically, as shown in FIG. 14, the unload lever 31 is moved from the first position (the third guide pin 40 is in the first position 52A) to the second position (the third guide pin 40 is in the second position 52B). Press down to the state of As a result, the unload lever 31 rotates downward (clockwise in FIGS. 13 and 14) with the third horizontal shaft 36 as a fulcrum until the third guide pin 40 reaches the first position 52A. As a result of this rotation, the second guide pin 44 moves above the first guide groove 24, disengages from the rear groove (second locking portion) 25C, shifts to the intermediate groove 24B, and the locked state is released ( (See FIG. 14). As a result, the control box 26 can be rotated downward together with the unload lever 31.
<Second stage>
When the unload lever 31 is further pushed down from the state of FIG. 14, the lower edge of the second guide groove 52 of the cam body 33 is pushed by the third guide pin 40, so that the cam body 33 is in the second position as shown in FIG. It rotates downward with the horizontal shaft 32 as a fulcrum. As the cam body 33 rotates, the first guide pin 35 moves relative to the cam body 33 and moves rearward (on the first cam groove 34A side) along the second cam groove 34B. The second guide pin 44 moves forward in the intermediate groove 24 </ b> B of the first guide groove 24. As the first guide pin 35 and the second guide pin 44 move, the control box 26 rotates downward.
<Third stage>
When the unload lever 31 is further pushed down from the state shown in FIG. 15, the cam body 33 further rotates downward as shown in FIG. As the cam body 33 rotates, the first guide pin 35 moves to the vicinity of the boundary between the second cam groove 34B and the first cam groove 34A. The second guide pin 44 moves to the vicinity of the boundary between the intermediate groove 24B of the first guide groove 24 and the front groove (first locking portion) 24A. As the first guide pin 35 and the second guide pin 44 move, the control box 26 further rotates downward.
<Fourth stage>
When the unload lever 31 is further pushed down from the state of FIG. 16, the cam body 33 further rotates downward as shown in FIG. As the cam body 33 rotates, the first guide pin 35 moves upward along the first cam groove 34A. The second guide pin 44 moves downward along the front groove (first locking portion) 24 </ b> A of the first guide groove 24. As the first guide pin 35 and the second guide pin 44 move, the control box 26 further rotates downward.
<Fifth stage>
When the unload lever 31 is further pushed down from the state shown in FIG. 17, the cam body 33 further rotates downward as shown in FIG. As the cam body 33 rotates, the first guide pin 35 moves to the upper end of the first cam groove 34A. As shown in FIG. 11, the second guide pin 44 is locked to the lower end of the front groove (first locking portion) 24 </ b> A of the first guide groove 24. Thereby, the left steering device 22 becomes the use position described above.

  As described above, according to the present invention, when the unload lever 31 is in the lifted position, the second guide pin 44 is locked to the rear groove (second locking portion) 24C of the first guide groove 24. The state (locked state) is established, and the downward rotation of the control box 26 is prevented. As a result, it is possible to prevent the driver from inadvertently depressing a portion other than the unload lever 31 (such as the left operation lever 30) to enter the load state.

  Further, from the state in which the unload lever 31 is in the lifted position, the unload lever 31 is rotated downward to move the third guide pin 40 from the first position 52A to the second position 52B, whereby the second guide pin 44 moves above the first guide groove 24 and is separated from the rear groove (second locking portion) 24C, and the locked state is released. That is, the locked state is not released unless the driver performs an operation of pushing down the unload lever 31. For this reason, it is possible to reliably prevent the driver from turning down the steering box 26 into a loaded state by pushing down a portion other than the unload lever 31 (such as the left operation lever 30). Further, when releasing the locked state, a special unlocking operation is not required other than the pushing-down operation of the unload lever 31, so that the operability is excellent.

  In addition, there is a biasing member (a tension spring 50) that biases the unload lever 31 in a direction in which the unload lever 31 is rotated upward with the third horizontal shaft 36 as a fulcrum (a direction in which the unload lever 31 is held at the first position). By doing so, the locked state can be reliably maintained. That is, unless the driver pushes down the unload lever 31 against the biasing member (the tension spring 50), the third guide pin 40 is maintained at the first position 52A. (Second engagement portion) The state (locked state) engaged with 24C is reliably maintained.

When the unload lever 31 is in the depressed position (load state), the second guide pin 44 of the unload lever 31 is locked to the front groove (first locking portion) 24A of the first guide groove 24. The Therefore, it is possible to prevent the unload lever 3 from resonating due to vibration during traveling and the unload lever 31 from jumping up due to the resonance and becoming unloaded.
Although the present invention has been described above, it should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

1 Working Machine 8 Driver's Seat 24 First Guide Groove 24A First Locking Section (Front Groove)
24C Second locking part (rear groove)
25 Support bracket 26 Control box 27 First horizontal axis 30 Operation lever (left operation lever)
31 Unload lever 32 Second horizontal shaft 33 Cam body 34 Cam groove 35 First guide pin 40 Third guide pin 44 Second guide pin 50 Biasing member (tensile spring)
52 2nd guide groove 52A 1st position 52B 2nd position

Claims (4)

The driver ’s seat,
A working device having a hydraulic actuator;
A support bracket provided on a side of the driver's seat and having a first guide groove;
A control box pivotally supported by the support bracket via a first horizontal axis and having an operation lever;
An unloading lever pivotally supported by the control box and operable to supply hydraulic oil to the hydraulic actuator by the swinging;
A cam body pivotally supported by the control box via a second horizontal axis and having a cam groove;
The support bracket changes its position in the cam groove in response to the swing of the unload lever, and when the unload lever is in the pushed down position, it is located in one of the cam grooves and in the raised position. A first guide pin located on the other side of the cam groove;
The unload lever changes its position in the first guide groove in response to the swinging of the unload lever, and is located in one of the first guide grooves when the unload lever is in the depressed position. A second guide pin located on the other side of the first guide groove when in the raised position;
The first guide groove includes a first locking portion that locks the second guide pin on one side of the first guide groove, and a second lock that locks the second guide pin on the other side of the first guide groove. A working machine having a locking portion. The unload lever is pivotally supported between the upper first position and the lower second position with respect to the cam body,
2. The work implement according to claim 1, wherein the second guide pin is detached from the second locking portion when the unload lever is rotated from the first position to the second position. The cam body has a second guide groove,
The unload lever is located in one of the second guide grooves when the unload lever is in the first position, and is located in the other of the second guide grooves when in the second position. The working machine according to claim 2, comprising a pin.   The work machine according to claim 2 or 3, further comprising a biasing member that applies a biasing force to rotate the unload lever upward to hold the unload lever in the first position.

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