JP2015067212A - Work vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a work vehicle which absorbs shape error of a machine body frame.SOLUTION: In the work vehicle, a transmission case 40 is fixed to an area at the inner side of beams, which are disposed spaced away from each other, by first pins 61 and second pins 72. A first attachment hole 14a, in which the first pin 61 is inserted without forming a gap therebetween, and a second attachment hole 14b, in which the second pin 72 is inserted forming a gap therebetween, are formed at each beam. Each first pin 61 inserted into the first attachment hole 14a is fixed to the transmission case 40, and each second pin 72 inserted into the second attachment hole 14b is fixed to the transmission case 40 and the beam.

Description

  The present invention relates to a work vehicle in which a transmission case is fixed by a first pin and a second pin inside a beam arranged at a predetermined interval.

  Conventionally, a mission case is fixed to a rear portion of a work vehicle such as a tractor (see, for example, Patent Document 1).

In the work vehicle disclosed in Patent Document 1, an upper mounting hole and a lower mounting hole are formed at the rear end of the body frame, and two fixing holes are formed in a rear axle case fixed to the transmission case.
The work vehicle disclosed in Patent Document 1 attaches bolts and the like to the upper mounting hole of the fuselage frame and the fixing hole of the rear axle case, and attaches bolts and the like to the lower mounting hole of the fuselage frame and the fixing hole of the rear axle case. By attaching it, the mission case is fixed to the fuselage frame.

  In the work vehicle disclosed in Patent Document 1, the upper and lower mounting holes and the two fixing holes are formed in the same shape, and the positions of the upper and lower mounting holes and the two fixing holes are only at predetermined positions. To fit.

Therefore, in the work vehicle disclosed in Patent Document 1, there is a possibility that the mission case cannot be fixed to the body frame when the shape error between the body frame and the mission case becomes large.
For example, other parts may be welded to the body frame for the purpose of reducing the number of parts and ensuring rigidity.

JP 2012-126147 A

  The present invention has been made in view of the above situation, and provides a work vehicle that can absorb the shape error of the body frame.

  In Claim 1, It is a work vehicle by which a mission case is fixed by the 1st pin and the 2nd pin inside the beam arranged at predetermined intervals, and the 1st pin is a crevice in the beam. A first mounting hole that is inserted without any gap and a second mounting hole that is inserted in a state where the second pin has a gap, and the first pin that is inserted into the first mounting hole includes A second pin fixed to the case and inserted into the second mounting hole is fixed to the mission case and the beam.

  According to a second aspect of the present invention, the second mounting hole is formed in an arc shape with the first pin as the center.

  As effects of the present invention, the following effects can be obtained.

  According to the work vehicle of the first aspect, it is possible to absorb the shape error of the body frame.

  According to the work vehicle of the second aspect, the shape error of the machine body frame can be absorbed more effectively.

The side view which showed the whole structure of the working vehicle which concerns on one Embodiment of this invention. The figure which shows a front axle case. (A) Side view. (B) Top view. The perspective view of a body frame. The side view of a body frame. Explanatory drawing of a mission case. (A) Side view. (B) Sectional drawing which shows a 1st attaching part and a 2nd attaching part. The disassembled perspective view of a mission case attaching part. The side view of a mission case attaching part. Explanatory drawing which shows the state which attached the 1st pin to the mission case. (A) Side view. (B) Sectional drawing. Explanatory drawing which shows the state which attached the 2nd pin to the mission case. (A) Side view. (B) Sectional drawing. Explanatory drawing which shows the state which fixed the 2nd pin. (A) Side view. (B) Sectional drawing. Explanatory drawing which shows the 2nd attachment hole of another embodiment. Explanatory drawing which shows a mode that a mission case is rotated.

  Next, an embodiment of the present invention will be described.

First, the whole structure of the work vehicle 1 which concerns on one Embodiment of this invention is demonstrated.
The work vehicle 1 of this embodiment is a tractor. However, the application target of the work vehicle 1 according to the present invention is not limited to the tractor.

In the following, the front-rear direction of the work vehicle 1 is defined with the arrow F direction shown in FIG.
Moreover, below, the up-down direction of the work vehicle 1 is prescribed | regulated by making the arrow U direction shown in FIG. 1 into an upward direction.
And below, the left-right direction of the work vehicle 1 is prescribed | regulated by making the arrow L direction shown in FIG.2 (b) into the left direction.

  As shown in FIG. 1, in the work vehicle 1, an airframe frame 10 is arranged with the longitudinal direction as the front-rear direction.

  The body frame 10 supports the engine 2 via an engine bracket at the front portion thereof. The engine 2 and the like are covered with a bonnet 3.

  The front part of the body frame 10 is supported by the pair of front wheels 4 via the front axle case 30. The rear part of the body frame 10 is supported by a pair of rear wheels 5 via a mission case 40 and a rear axle case 51.

A driving operation unit 6 is disposed on the upper part of the body frame 10. The driving operation unit 6 includes a steering handle 6a and a seat 6b.
The steering handle 6a is configured such that the work vehicle 1 can be steered by changing the steering angle of the pair of front wheels 4 according to the amount of rotational operation. The seat 6b is disposed above the pair of rear wheels 5 so that the driver can sit.

  A work implement mounting device 7 is provided at the rear portion of the driving operation unit 6. The work implement mounting device 7 is configured such that a work implement such as a rotary tiller is connected to the rear end of the top link 7a and the rear end of the lower link 7b, so that the work implement is attached to the rear end of the work vehicle 1. Installing.

  The work vehicle 1 corrects the loss of weight balance in the front-rear direction caused by the work machine being mounted by attaching the front hitch 20 to which the weight is mounted to the front end of the body frame 10.

  As shown in FIGS. 1 and 2, a front axle case 30 is attached to the front portion of the body frame 10.

The front axle case 30 is a hollow member whose longitudinal direction is the left-right direction. A shaft portion 30 a that protrudes in the front-rear direction is formed at the left and right central portion of the front axle case 30.
A pair of front wheels 4 are attached to the left and right side surfaces of the front axle case 30 via a pair of front axles 31.

  Such a front axle case 30 is supported by the body frame 10 and the front axle brackets 13 and 21 of the front hitch 20.

As shown in FIG. 1, a mission case 40 that houses the transmission is attached to the rear portion of the body frame 10 via a mission case attachment portion 60.
A top link 7 a of the work implement mounting device 7 is rotatably connected to the rear portion of the mission case 40.
The configuration of the mission case mounting portion 60 will be described in detail later.

The mission case 40 supports a pair of rear axle cases 51 on both the left and right sides (see FIG. 5A).
A pair of rear wheels 5 is attached to the pair of rear axle cases 51 via a pair of rear axles 52.
The lower link 7b of the work implement mounting device 7 is rotatably connected to the transmission case 40 or the pair of rear axle cases 51.

  The work vehicle 1 is configured to be able to transmit the power of the engine 2 that has been shifted to the pair of front wheels 4 via the pair of front axles 31 after the power of the engine 2 is shifted by the transmission. The rear axle 52 can be transmitted to the pair of rear wheels 5.

The work vehicle 1 travels by rotating the pair of front wheels 4 and the pair of rear wheels 5 by transmitting the power of the engine 2 to the pair of front wheels 4 and the pair of rear wheels 5.
The work vehicle 1 is configured to be able to transmit the power of the engine 2 shifted by the transmission to the work implement. Thereby, the work vehicle 1 drives the working machine.

  Next, the configuration of the body frame 10 will be described.

  As shown in FIG. 3, the fuselage frame 10 includes a pair of beams 11, a pair of reinforcing plates 12, a front axle bracket 13, and a pair of attachment members 14.

The pair of beams 11 are disposed with a predetermined interval in the left-right direction while the longitudinal direction is the front-rear direction.
The pair of beams 11 is formed by bending the upper part of the plate-like member arranged so that the plate surfaces face each other outward in the left-right direction (on the opposite beam side, that is, the side away from the other beam 11). Is bent inward in the left-right direction (on the opposite beam side, that is, on the side approaching the opposite beam 11).

The lower portions of the pair of beams 11 are formed in a shape that gradually spreads in an inclined manner from the front to the rear in a side view. The upper parts of the pair of beams 11 are formed in a shape parallel to the front-rear direction in a side view.
That is, the vertical width of the pair of beams 11 gradually increases toward the rear.

The pair of reinforcing plates 12 are plate-like members extending in the front-rear direction from the front end portion of the body frame 10 to the vicinity of the front-rear center portion of the body frame 10. That is, the longitudinal direction of the pair of reinforcing plates 12 is the front-rear direction. The pair of reinforcing plates 12 are arranged on the opposing plate surfaces of the pair of beams 11 such that the plate surfaces are opposed to each other.
The pair of reinforcing plates 12 are arranged on the pair of beams 11 such that the upper portions thereof do not protrude above the pair of beams 11.

Such a pair of reinforcing plates 12 are welded to the opposing plate surfaces of the pair of beams 11, that is, the inner surfaces in the left-right direction.
At this time, the pair of reinforcing plates 12 are welded so that the welded portions are dispersed over the entire reinforcing plate 12 by, for example, welding with a certain interval along the shape of the outer edge portion.

  As a result, the pair of beams 11 are dispersed over a wide range and the pair of reinforcing plates 12 are welded. Therefore, the work vehicle 1 can reduce welding distortion of the pair of beams 11 caused by welding the pair of reinforcing plates 12.

The front axle bracket 13 is a hollow member whose longitudinal direction is the left-right direction. The front axle bracket 13 is formed in a shape in which a cylindrical member having a front-rear direction as a cylinder axis direction is attached to a lower end portion of a left and right central portion of a substantially box-shaped member having both left and right side surfaces opened.
The lower portion of the front axle bracket 13 is formed in a shape that is inclined downward with respect to the left-right direction so as to gradually extend downward toward the center in the left-right direction.

  A bearing that supports the shaft portion 30 a of the front axle case 30 is provided at a lower end portion of the center portion in the left-right direction of the front axle bracket 13, that is, a hole portion corresponding to the tubular member.

As shown in FIGS. 2 and 3, the front axle bracket 21 attached to the front hitch 20 is configured similarly to the front axle bracket 13 of the body frame 10.
The two front axle brackets 13 and 21 support the front axle case 30 by inserting the shaft portion 30a of the front axle case 30 into the bearing.

The left and right end portions of the front axle bracket 13 are welded to the front and rear intermediate portions of the pair of reinforcing plates 12.
At this time, the left and right ends of the front axle bracket 13 are welded along the shape of the outer edge.

That is, the front axle bracket 13 is not directly welded to the pair of beams 11.
As a result, the pair of beams 11 receives the welding distortion of the pair of reinforcing plates 12 by welding the front axle bracket 13 in a wide range of the pair of beams 11, so that the welding distortion of the pair of beams 11 can be reduced. it can.

As shown in FIGS. 3 and 4, the pair of attachment members 14 are plate-like members arranged so that the plate surfaces face each other. The pair of attachment members 14 are formed in a shape that smoothly spreads radially in the vertical direction as going backward.
The pair of attachment members 14 are formed with a first attachment hole 14a, a second attachment hole 14b, and two bolt holes 14c.

The first attachment hole 14 a is formed in the upper part of the rear end portions of the pair of attachment members 14. The first attachment hole 14a penetrates the plate surface of the attachment member 14 in the left-right direction.
The first mounting hole 14a is formed in a substantially circular shape when viewed from the side.

  The second mounting hole 14b is formed below the first mounting hole 14a. The second mounting hole 14b is formed in substantially the same shape as the first mounting hole 14a.

  Each bolt hole 14c is disposed in front of the second mounting hole 14b. Each bolt hole 14c is arrange | positioned at intervals in the up-down direction. Each bolt hole 14c is formed in a substantially circular shape when viewed from the side, and penetrates the plate surface of the mounting member 14 in the left-right direction. A female thread portion is formed on the inner peripheral surface of each bolt hole 14c.

As shown in FIG. 3, the front portions of the pair of attachment members 14 are welded to the pair of beams 11.
At this time, the front part of a pair of attachment member 14 is welded along the shape of the outer edge part.

  That is, the body frame 10 of the present embodiment is configured as an integral part in which a pair of beams 11, a pair of reinforcing plates 12, a front axle bracket 13, and a pair of attachment members 14 are integrally attached by welding.

Thereby, the work vehicle 1 suppresses a decrease in rigidity of the body frame 10 due to variations in bolt fastening force, and ensures the rigidity of the body frame 10.
In addition, the work vehicle 1 reduces the number of fastening parts for attaching the pair of reinforcing plates 12 and the like to the pair of beams 11.

  The mission case 40 is fixed to the inside of the pair of attachment members 14 of the body frame 10, that is, to the opposing plate surfaces of the pair of attachment members 14 (see FIG. 10).

  Next, the structure of the part fixed to the body frame 10 of the mission case 40 will be described.

As shown in FIG. 5, a pair of first pin mounting portions 41 and a pair of second pin mounting portions 42 are formed on the left and right side surfaces of the mission case 40.
The pair of first pin mounting portions 41 are configured in the same manner except for the arrangement position. The pair of second pin mounting portions 42 are configured in the same manner except for the arrangement position.

  Therefore, hereinafter, only the first pin mounting portion 41 and the second pin mounting portion 42 disposed on the left side of the work vehicle 1 will be described, and the first pin mounting portion 41 disposed on the left side of the work vehicle 1 and A description of the second pin mounting portion 42 is omitted.

The first pin mounting portion 41 is a substantially circular hole with a bottom surface formed in a side view, and is formed on the front side of the mission case 40. The first pin mounting portion 41 has an inner diameter on one side (outside of the transmission case 40) larger than an inner diameter on the other side (inside of the transmission case 40), and a step is formed in the left and right middle portions.
As for the 1st pin attachment part 41, the part with a large internal diameter is formed as the large diameter part 41a. As for the 1st pin attachment part 41, the part with a small internal diameter is formed as the small diameter part 41b.

  The large diameter portion 41 a has an inner diameter that is substantially the same as the inner diameter of the first mounting hole 14 a of the mounting member 14.

  An internal thread portion is formed on the inner peripheral surface of the small diameter portion 41b.

  The second pin attachment portion 42 is formed below the first pin attachment portion 41. The distance between the centers of the first pin attachment portion 41 and the second pin attachment portion 42 is substantially the same distance as the distance between the centers of the first attachment hole 14a and the second attachment hole 14b of the attachment member 14 ( (Refer FIG.8 (b)).

The second pin mounting portion 42 is formed in the same shape as the first pin mounting portion 41 except that the inner diameter of the large diameter portion 42a is smaller than the inner diameter of the large diameter portion 41a of the first pin mounting portion 41. .
That is, the large-diameter portion 42 a of the second pin attachment portion 42 is smaller than the second attachment hole 14 b of the attachment member 14.
For this reason, the 2nd pin attachment part 42 can overlap with the 2nd attachment hole 14b within a predetermined range (refer Fig.8 (a)).

  Such a mission case 40 is manufactured by casting and then machined to form a first pin mounting portion 41 and a second pin mounting portion 42. For this reason, the 1st pin attaching part 41 and the 2nd pin attaching part 42 ensure high position accuracy.

  Next, the configuration of the pair of mission case mounting portions 60 for fixing the mission case 40 to the body frame 10 will be described.

  As shown in FIG. 1, the pair of mission case attachment portions 60 are disposed on the left and right sides of the work vehicle 1 at the rear portion of the work vehicle 1. The pair of mission case mounting portions 60 are configured in the same manner except for the arrangement position.

  For this reason, below, only the mission case mounting portion 60 disposed on the left side of the work vehicle 1 will be described, and the description of the mission case mounting portion 60 disposed on the left side of the work vehicle 1 will be omitted.

  As shown in FIGS. 6 and 7, the mission case attachment portion 60 is disposed on the left side (outside) of the attachment member 14. The mission case mounting portion 60 includes a first pin 61, a plate 71, and a second pin 72.

  The first pin 61 is configured by inserting the shaft portion of the bolt 61a into the boss 61b.

  The bolt 61 a is formed in a shape that can be screwed into the small diameter portion 41 b of the first pin mounting portion 41 of the mission case 40.

The boss 61b has an outer diameter on one side (outer side) larger than an inner diameter on the other side (inner side). The other side (small diameter side) of the boss 61 b has an outer diameter slightly smaller than the inner diameter of the large diameter portion 41 a of the first pin mounting portion 41 and the first mounting hole 14 a of the mounting member 14.
One side (large diameter side) of the boss 61b has an outer diameter larger than the inner diameter of the large diameter portion 41a of the first pin mounting portion 41 and the first mounting hole 14a of the mounting member 14.
The axial length of the boss 61b is shorter than the axial length of the bolt 61a.

  In such a first pin 61, the boss 61b is inserted into the first mounting hole 14a.

The plate 71 is a plate-like member arranged so that the plate surface faces the mounting member 14. The plate 71 is formed in a shape that gently extends in the up-down direction toward the front in a side view.
Two bolt mounting portions 71 a are formed on the plate 71.

The two bolt mounting portions 71 a are holes that are substantially circular in a side view and penetrate the plate surface of the plate 71. Each bolt mounting portion 71a has an inner diameter larger than the inner diameter of the bolt hole 14c.
Each bolt mounting portion 71 a is disposed on both the upper and lower sides of the front end portion of the plate 71. The distance between the centers of the bolt mounting portions 71a is the same distance as the distance between the centers of the bolt holes 14c.

Bolts 71b having heads larger than the respective bolt mounting portions 71a are screwed into the respective bolt holes 14c of the mounting member 14 through the respective bolt mounting portions 71a.
Thereby, the plate 71 is fixed to the attachment member 14.

  The second pin 72 is configured by inserting the shaft portion of the bolt 72a into the boss 72b.

  The bolt 72 a is formed in a shape that can be screwed into the small diameter portion 42 b of the second pin mounting portion 42 of the mission case 40.

The boss 72b has an outer diameter slightly smaller than the inner diameter of the large-diameter portion 42a of the second pin mounting portion 42. That is, the boss 72 b has an outer diameter that is smaller than the inner diameter of the second mounting hole 14 b of the mounting member 14. The boss 72b has an outer diameter smaller than the outer diameter of the other side (smaller diameter side) of the boss 61b of the first pin 61.
The axial length of the boss 72b is shorter than the axial length of the bolt 72a.

Such a second pin 72 is inserted into a hole formed in the rear end portion of the plate 71, and the outer peripheral edge portion of the boss 72 b is welded to the plate 71, thereby being configured integrally with the plate 71.
The boss 72 b of the second pin 72 is inserted into the second mounting hole 14 b when the plate 71 is fixed to the mounting member 14. At this time, a gap is formed between the boss 72b of the second pin 72 and the second mounting hole 14b.

  In the mission case mounting portion 60, the first pin 61 is inserted into the first pin mounting portion 41 of the mission case 40 through the mounting member 14, and the second pin 72 is first through the mounting member 14. The mission case 40 is fixed to the body frame 10 by being inserted into the two-pin mounting portion 42 and being fixed to the mounting member 14 (see FIG. 10B).

  Next, the procedure of the assembling process for fixing the mission case 40 to the body frame 10 by the mission case mounting portion 60 will be described with reference to FIGS.

  Note that when the assembly process is performed, the body frame 10 and the transmission case 40 are aligned in height with a jig or the like.

The mission case 40 is fixed to the left and right sides by a pair of mission case mounting portions 60. The procedure for fixing the mission case 40 is the same on both the left and right sides.
Therefore, only the procedure for fixing the left side of the mission case 40 to the airframe frame 10 will be described below, and the procedure for fixing the left side of the mission case 40 to the airframe frame 10 will be omitted.

In the following, it is assumed that the body frame 10 has a shape error due to the influence of welding distortion. That is, the first mounting hole 14a, the second mounting hole 14b, and each bolt hole 14c of the mounting member 14 are not arranged at the intended positions.
In this case, the first mounting hole 14a and the second mounting hole 14b are disposed at positions shifted from the first pin mounting portion 41 and the second pin mounting portion 42 that are disposed at the intended positions by casting. The Rukoto.

  First, as shown in FIG. 8, in the assembly process, the transmission case 40 is brought close to the mounting member 14 (airframe 10), and the positions of the center of the first mounting hole 14a and the center of the first pin mounting portion 41 are set. Match.

  In the assembly step, the boss 61b of the first pin 61 is inserted into the first mounting hole 14a and the large diameter portion 41a of the first pin mounting portion 41 of the transmission case 40.

The boss 61b of the first pin 61 has an outer diameter slightly smaller than the inner diameter of the first mounting hole 14a and the large diameter portion 41a of the first pin mounting portion 41.
For this reason, the first pin 61 is inserted into the first attachment hole 14a and the large-diameter portion 41a of the first pin attachment portion 41 without a gap.

In the present embodiment, the first pin 61 is inserted without any gap between the first pin 61 and the first mounting hole 14a so that the first pin 61 can be inserted into the first mounting hole 14a. This means that the first pin 61 is inserted in a state where is formed.
That is, the first pin 61 is inserted into the first mounting hole 14a only at a predetermined position.

  After inserting the boss 61b of the first pin 61, the bolt 61a of the first pin 61 is screwed into the small-diameter portion 41b of the first pin mounting portion 41 of the transmission case 40 in the assembly process.

  Thereby, the first pin 61 inserted into the first mounting hole 14 a is fixed to the mission case 40.

At this time, the mission case 40 is connected to the mounting member 14 (the beam 11 of the machine body frame 10) only by the first pin 61.
For this reason, the mission case 40 is in a state of being rotatable relative to the attachment member 14 with the first pin 61 as the center of rotation.

That is, the work vehicle 1 of the present embodiment first supports the mission case 40 by the first pin 61 in the assembly process.
Therefore, the work vehicle 1 ensures the shape accuracy and rigidity of the first pin 61 by making the outer diameter of the boss 61b of the first pin 61 larger than the outer diameter of the boss 72b of the second pin 72.

  After the first pin 61 is inserted, as shown in FIGS. 8 and 9, in the assembly process, the second mounting hole 14b of the mounting member 14 and the large-diameter portion 42a of the second pin mounting portion 42 of the transmission case 40. And the boss 72b of the second pin 72 is inserted.

  Here, the second mounting hole 14 b is arranged at a position where the center is shifted from the center of the second pin mounting portion 42 due to the influence of welding distortion.

Therefore, the work vehicle 1 of the present embodiment can form the second mounting hole 14b in a substantially circular shape in a side view having an inner diameter larger than the inner diameter of the second pin mounting portion 42, and can insert the boss 72b of the second pin 72. It is expanding the scope.
According to this, the work vehicle 1 has the second pin 72 in the second mounting hole 14b and the large-diameter portion 42a of the second pin mounting portion 42 even when a shape error of the machine body frame 10 occurs due to the influence of welding distortion. Boss 72b can be inserted.

The boss 72b of the second pin 72 has an outer diameter slightly smaller than the large-diameter portion 42a of the second pin mounting portion 42.
For this reason, the second pin 72 is inserted into the large-diameter portion 42a of the second pin attachment portion 42 without a gap and is inserted with a gap in the second attachment hole 14b.

In the present embodiment, the fact that the second pin 72 is inserted with a gap means that the second pin 72 can be inserted into the second mounting hole 14b between the second pin 72 and the second mounting hole 14b. This means that the second pin 72 is inserted in a state in which a gap larger than a certain gap is formed.
That is, the second pin 72 can be inserted into the second mounting hole 14b within a predetermined range.

  After inserting the boss 72b of the second pin 72, the bolt 72a of the second pin 72 is screwed into the small diameter portion 42b of the second pin mounting portion 42 of the mission case 40 in the assembly process.

The second pin 72 inserted into the second mounting hole 14b is fixed to the mission case 40 and the beam 11 in this way.
Thereby, the plate 71 to which the second pin 72 is welded is attached to the mission case 40.

  After inserting the second pin 72, as shown in FIGS. 9 and 10, in the assembling process, each bolt 71b is inserted into each bolt mounting portion 71a of the plate 71, and each bolt hole 14c of the mounting member 14 is inserted. Screw each bolt 71b.

  Here, when the shape error of the machine body frame 10 occurs as in the present embodiment, each bolt mounting portion 71a is displaced from the center of each bolt hole 14c according to the position of the second pin 72. Will be placed at the position.

Therefore, the work vehicle 1 forms each bolt mounting portion 71a in a substantially circular shape in side view having an inner diameter larger than the inner diameter of each bolt hole 14c, and widens the range in which each bolt 71b can be inserted into each bolt mounting portion 71a. It is.
According to this, the work vehicle 1 can screw each bolt 71b into each bolt hole 14c even when the shape error of the machine body frame 10 occurs due to the influence of welding distortion.

  Thereby, the mission case 40 is fixed inside the beam 11 by the first pin 61 and the second pin 72.

According to this, the work vehicle 1 can fix the mission case 40 to the body frame 10 without causing an assembly failure such that the second pin 72 cannot be inserted into the second pin mounting portion 42 of the mission case 40.
That is, the work vehicle 1 can reliably fix the transmission case 40 to the machine body frame 10 even when the machine body frame 10 in which a plurality of parts are integrally formed by welding is adopted.

  Therefore, the work vehicle 1 can absorb the shape error of the body frame 10 while ensuring the rigidity of the body frame 10 and reducing the number of parts.

Next, another embodiment of the second mounting hole 14b of the mounting member 14 will be described.
In addition, since it is the same as that of this embodiment about parts other than the 2nd attachment hole 114b of the attachment member 14, the code | symbol similar to this embodiment is attached | subjected and the description is abbreviate | omitted.

As shown in FIG. 11, the second mounting hole 114 b is formed in a substantially arc shape in a side view with the first mounting hole 14 a, that is, the first pin 61 as the center. The second mounting hole 114 b has a vertical width longer than the outer diameter of the boss 72 b of the second pin 72.
When the boss 72b is inserted into the second mounting hole 114b, the second pin 72 can be moved long from the front side surface to the rear side surface of the second mounting hole 114b.

  FIG. 12 shows that the shape error of the fuselage frame 10 due to welding distortion accumulates, and the position of the fuselage frame 10 is relative to the mission case 40 when the first pin 61 is inserted into the first pin mounting portion 41 of the mission case 40. The state which has shifted | deviated largely is shown.

  In such a case, in the assembling step, the mission case 40 can be rotated with the first pin 61 as the center of rotation, and the position of the body frame 10 can be adjusted with respect to the mission case 40.

  Accordingly, in another embodiment, the second mounting hole 114b is formed in a substantially arc shape when viewed from the side centered on the first pin 61, that is, along the direction of absorbing the shape error of the body frame 10, and the second mounting hole is formed. The adjustment amount of the body frame 10 with respect to the mission case 40 can be ensured without making the hole 114b larger than necessary.

  According to this, the work vehicle 1 can absorb the shape error of the body frame 10 more effectively.

  The positional relationship between the first mounting hole and the second mounting hole is not limited to this embodiment. For example, the first mounting hole is formed below the mounting member, and the second mounting hole is formed. You may form in the upper side of an attachment member.

  The shape of the second mounting hole is not limited to the present embodiment as long as the second pin can be inserted with a gap.

DESCRIPTION OF SYMBOLS 1 Work vehicle 10 Airframe frame 11 Beam 14a First attachment hole 14b Second attachment hole 40 Mission case 61 First pin 72 Second pin

Claims (2)

A work vehicle in which a mission case is fixed by a first pin and a second pin inside a beam arranged at a predetermined interval,
The beam includes
A first mounting hole into which the first pin is inserted without a gap;
A second mounting hole inserted with the second pin having a gap;
Formed,
The first pin inserted into the first mounting hole is fixed to the mission case,
A second pin inserted into the second mounting hole is fixed to the mission case and the beam;
Work vehicle. The second mounting hole is
Formed in an arc shape centered on the first pin,
The work vehicle according to claim 1.

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