The present disclosure relates to a bucket and a work vehicle.
For example, WO2004/023001 (PTL 1) discloses a bucket for an earthmoving machine.
As disclosed in the above-mentioned PTL 1, a bucket is known that is mounted in a work vehicle such as a hydraulic excavator and used for excavating soil. Such a bucket is required to allow a larger amount of soil to be loaded therein for achieving efficient excavation.
An object of the present disclosure is to provide a bucket allowing efficient excavation and a work vehicle including such a bucket.
A bucket according to the present disclosure is a bucket coupled to an arm of a work implement to be pivotable about a prescribed axis. The bucket includes a bottom plate, a pair of side plates, a bracket, and a front lip. The bottom plate faces an opening of the bucket. The pair of side plates is disposed to face each other on both sides of the bottom plate. The bracket is provided on a back surface of the bottom plate. The bracket is coupled to the arm on the prescribed axis. The front lip is provided along the opening. The bottom plate includes a first inclined portion on a side where the bracket is attached. The bottom plate further includes a deepest portion. At the deepest portion, a length from a first reference straight line to the bottom plate is maximum. The first reference straight line passes through the prescribed axis and a tip end of the front lip. An angle formed between a second reference straight line and the front lip is smaller than an angle formed between the second reference straight line and the first inclined portion. The second reference straight line is orthogonal to the first reference straight line and passes through the deepest portion. An intersection point between the first reference straight line and the second reference straight line is located close to the front lip on the first reference straight line.
A work vehicle according to the present disclosure includes a vehicular body and a work implement. The work implement is attached to the vehicular body. The work implement includes a boom, an arm, and the bucket. The boom is pivotably coupled to the vehicular body. The arm is pivotably coupled to the boom. The bucket is pivotably coupled to the arm.
According to the present disclosure, a bucket allowing efficient excavation and a work vehicle including such a bucket can be provided.
Embodiments of the present disclosure will be hereinafter described with reference to the accompanying drawings. In the drawings referred to below, the same or corresponding components will be denoted by the same reference characters.
Traveling unit 15 includes a pair of crawler belts 15Cr and a travel motor 15M. Hydraulic excavator 100 can travel by rotation of crawler belts 15Cr. Travel motor 15M is provided as a drive source of traveling unit 15. Traveling unit 15 may include a wheel (tire).
Revolving unit 13 is provided on traveling unit 15. Revolving unit 13 can swing about the center of swing 41 with respect to traveling unit 15. The center of swing 41 corresponds to an axis extending in the up-down direction. Revolving unit 13 includes a cab (operator's cab) 14. Operator's cab 14 is provided with an operator's seat 14S on which an operator sits. The operator inside operator's cab 14 can operate hydraulic excavator 100.
Revolving unit 13 includes an engine compartment 19 and a counter weight that is provided in a rear portion of revolving unit 13. Engine compartment 19 accommodates an engine, a hydraulic oil tank, an air cleaner, a hydraulic pump, and the like.
Work implement 12 is attached to vehicular body 11. Work implement 12 is attached to revolving unit 13. Work implement 12 performs operations such as excavation of soil. Work implement 12 includes a boom 16, an arm 17, and a bucket 50.
Boom 16 is pivotably coupled to vehicular body 11 (revolving unit 13) through a boom pin 23. Arm 17 is pivotably coupled to boom 16 through an arm pin 24. Bucket 50 is pivotably coupled to arm 17 through a bucket pin 25. Bucket 50 is coupled to arm 17 to be pivotable about a center axis 110. Bucket pin 25 has a pin shape and extends along center axis 110. Center axis 110 corresponds to a pivot axis of bucket 50.
Work implement 12 further includes boom cylinders 20A and 20B, an arm cylinder 21, and a bucket cylinder 22.
Boom cylinders 20A and 20B, arm cylinder 21, and bucket cylinder 22 each are a hydraulic cylinder driven by hydraulic oil. Boom cylinders 20A and 20B, which are provided as one pair, each are disposed on a corresponding one of both sides of boom 16, and operate boom 16 to pivot. Arm cylinder 21 operates arm 17 to pivot. Bucket cylinder 22 operates bucket 50 to pivot.
Boom 16, arm 17, and bucket 50 have pivot axes that extend in parallel with each other. The pivot axes of boom 16, arm 17, and bucket 50 each extend horizontally.
Hydraulic excavator 100 is a backhoe type configured such that bucket 50 is attached thereto so as to face an operator.
The structure of bucket 50 will then be described in detail.
As shown in
In the following description about the structure of buckets 50, the right-left direction corresponds to a direction in which the pivot axis (center axis 110) of bucket 50 extends. The front-rear direction corresponds to a direction orthogonal to the right-left direction. The side on which the pivot axis of bucket 50 exists corresponds to a rear side while the side opposite to the rear side corresponds to a front side. The right-hand side of bucket 50 that is disposed to face the front side corresponds to a right side while the left-hand side of bucket 50 that is disposed to face the front side corresponds to a left side. The up-down direction corresponds to a direction orthogonal to planes extending in the front-rear direction and the right-left direction. The side on which bucket 50 opens (has opening 51) corresponds to an upside while the side opposite to the upside corresponds to a downside. The above-mentioned directions are defined with respect to the posture of bucket 50 that is raised in the state where excavated objects such as soil are loaded in bucket 50.
Bucket 50 includes a bottom plate 60, a pair of side plates 81 (81L, 81R), a bracket 86, and a front lip 72. Bottom plate 60, the pair of side plates 81, and front lip 72 each are formed of a plate member. A space surrounded by bottom plate 60, the pair of side plates 81, and front lip 72 is provided such that excavated objects such as soil are loaded therein.
Bottom plate 60 faces opening 51 of bucket 50. Bottom plate 60 opens toward opening 51 in the up-down direction. The pair of side plates 81 is disposed to face each other on both sides of bottom plate 60. The pair of side plates 81 is connected to both ends of bottom plate 60 in the right-left direction. Side plates 81 are provided as one pair on the respective right and left sides. A side plate 81L is provided on the left side of bucket 50 while a side plate 81R is provided on the right side of bucket 50.
Bottom plate 60 is provided in parallel with the pivot axis of bucket 50 (center axis 110). Side plate 81 is provided in the direction crossing the pivot axis of bucket 50 (center axis 110). Side plate 81 is provided in the direction orthogonal to the pivot axis of bucket 50 (center axis 110).
The length of bucket 50 in the front-rear direction is increased toward the opening edge of opening 51 in the up-down direction. The area of the opening of the cross section of bucket 50 that is taken along a plane orthogonal to the up-down direction is increased toward the opening edge of opening 51 in the up-down direction.
Bottom plate 60 includes a bottom portion 61. Bottom portion 61 forms a bottom part of bottom plate 60 when viewed from opening 51. Bottom portion 61 has a curved shape in a side view seen in the axial direction of center axis 110 (side views shown in
In a view of a cross section taken along the plane orthogonal to center axis 110, bottom plate 60 has a linear-shaped cross section that extends obliquely upward in the frontward direction from the end of bottom portion 61 on the front side toward the opening edge of opening 51. In a view of a cross section taken along the plane orthogonal to center axis 110, bottom plate 60 has a linear-shaped cross section that entirely extends obliquely upward in the rearward direction from the end of bottom portion 61 on the rear side toward the opening edge of opening 51.
Bracket 86 is provided on the back surface (the outer surface on the rear side) of bottom plate 60. Bracket 86 is a member for coupling bucket 50 to work implement 12 (arm 17) in
Bracket 86 includes a base member 89 and a plurality of plates 87. Base member 89 is connected to bottom plate 60 from the outside of bucket 50. Base member 89 has a cross section formed in a mound shape protruding rearward from bottom plate 60 and extends in a plate shape in the right-left direction. Plate 87 is connected to base member 89. Plate 87 is formed of a plate member having a thickness extending in the right-left direction. Plate 87 extends to protrude rearward from base member 89. The plurality of plates 87 are spaced apart from each other in the right-left direction.
Bracket 86 is provided with holes 88 and 90. Hole 88 is provided to pass through plate 87 in the right-left direction (in the thickness direction of plate 87). Hole 88 is provided to pass through the plurality of plates 87 in the right-left direction. Hole 88 has its center on center axis 110 serving as a pivot axis of bucket 50. Hole 88 has a circular opening centering on center axis 110. Bucket pin 25 is inserted into hole 88, and thereby, bucket 50 is coupled to arm 17 to be pivotable about center axis 110 (also see
Hole 90 is provided to pass through plate 87 in the right-left direction (in the thickness direction of plate 87). Hole 90 is provided to pass through the plurality of plates 87 in the right-left direction. Hole 90 has its center on a center axis 111. Hole 90 has a circular opening centering on center axis 111. Center axis 111 extends in parallel with center axis 110. Center axis 111 is located below center axis 110. A pin for coupling bucket 50 to bucket cylinder 22 in
Front lip 72 is provided along opening 51. Front lip 72 faces bracket 86 in the front-rear direction. Front lip 72 is connected to the end of bottom plate 60 on the front side. In a side view, front lip 72 has a prescribed thickness and linearly extends obliquely upward in the frontward direction. Front lip 72 is formed of a plate member having a prescribed thickness. Front lip 72 is greater in thickness than bottom plate 60. A tooth 76 is connected to front lip 72 via a tooth adapter 75.
Bottom plate 60 includes a first inclined portion 67 and a second inclined portion 68. First inclined portion 67 and second inclined portion 68 are provided on the side where bracket 86 is attached. First inclined portion 67 is contiguous to bottom portion 61. First inclined portion 67 linearly extends obliquely upward in the rearward direction from the end of bottom portion 61 on the rear side. Second inclined portion 68 is contiguous to first inclined portion 67. Second inclined portion 68 is provided along an opening 51. Second inclined portion 68 is bent at first inclined portion 67 and extends to the opening edge of opening 51. Second inclined portion 68 extends linearly from first inclined portion 67 obliquely upward in the rearward direction at an inclination different from that of first inclined portion 67. In a side view, bottom plate 60 has a bent shape that is bent at the boundary between first inclined portion 67 and second inclined portion 68.
Each side plate 81 is connected to a corresponding one of both ends of bottom plate 60 in the axial direction of center axis 110. Side plate 81 is formed of a plate member having a thickness extending in the right-left direction (in the axial direction of center axis 110).
Side plate 81 includes a side lip 82. Side lip 82 is provided along opening 51. Side lip 82 is provided at the same height as front lip 72 in the up-down direction. Side lip 82 is formed of a plate member having a prescribed thickness. Side lip 82 is greater in thickness than other portions of side plate 81. A side cutter 77 is fixed to side lip 82. Side cutter 77 is provided at a position closer to front lip 72 than to bracket 86 in the front-rear direction.
A reinforcement member 91 is provided in a corner portion formed between side plate 81 (81L, 81R) and bottom plate 60. Reinforcement member 91 is provided inside bucket 50. Reinforcement member 91 is provided across first inclined portion 67 and second inclined portions 68.
Front lip 72, side lip 82 of side plate 81L, first inclined portion 67, and side lip 82 of side plate 81R are provided to surround opening 51. First inclined portion 67 is provided below front lip 72, side lip 82, and first inclined portion 67.
As shown in
A length H from first reference straight line 121 to bottom plate 60 varies in the linear direction along first reference straight line 121.
Bottom plate 60 includes a first deepest portion 62 (corresponding to the “deepest portion” in claim 1). First deepest portion 62 is a part of bottom portion 61. At first deepest portion 62, length H from first reference straight line 121 to bottom plate 60 has a maximum value (Hmax). First deepest portion 62 is a deepest portion inside bucket 50 with respect to first reference straight line 121.
A second reference straight line 122 is defined that is orthogonal to first reference straight line 121 and that passes through first deepest portion 62. Hmax corresponds to a length of second reference straight line 122 from first reference straight line 121 to first deepest portion 62. In the linear direction along first reference straight line 121, length H from first reference straight line 121 to bottom plate 60 is decreased from first deepest portion 62 toward the front side and decreased from first deepest portion 62 toward the rear side.
Also, an angle β formed between second reference straight line 122 and front lip 72 is smaller than an angle α formed between second reference straight line 122 and first inclined portion 67 (β<α). In other words, angle α formed between second reference straight line 122 and first inclined portion 67 is larger than angle β formed between second reference straight line 122 and front lip 72.
When angle α is in a range exceeding 20° and equal to or less than 45° (20°<α≤45°), angle β is in a range equal to or less than 20° (β≤20°). When angle α is in a range equal to or greater than 30° and equal to or less than 40° (30°≤α≤40°), angle β is in a range less than 30°. The sum of angle α and angle β is in a range exceeding 50° and equal to or less than 60° (50<α+β≤60°).
An angle γ formed between second reference straight line 122 and second inclined portion 68 is smaller than angle α formed between second reference straight line 122 and first inclined portion 67 (γ<α). Angle γ formed between second reference straight line 122 and second inclined portion 68 is smaller than angle β formed between second reference straight line 122 and front lip 72 (γ<β). Angle γ is in a range equal to or greater than 15° and equal to or less than 20° (15°≤γ≤20°).
It should be noted that angle γ formed between second reference straight line 122 and second inclined portion 68 may be equal to or greater than angle β formed between second reference straight line 122 and front lip 72 (γ≥β).
An intersection point P between first reference straight line 121 and second reference straight line 122 is located close to front lip 72 on first reference straight line 121. Intersection point P between first reference straight line 121 and second reference straight line 122 is located close to front lip 72 with respect to center axis 110 on first reference straight line 121. A length Lb of first reference straight line 121 from intersection point P between first reference straight line 121 and second reference straight line 122 to tip end 73 of front lip 72 is shorter than a length La from intersection point P between first reference straight line 121 and second reference straight line 122 to center axis 110 (Lb<La).
The volume of bucket 50 on the rear side with respect to second reference straight line 122 is greater than the volume of bucket 50 on the front side with respect to second reference straight line 122. The volume of bucket 50 on the rear side with respect to second reference straight line 122 may be equal to or less than the volume of bucket 50 on the front side with respect to second reference straight line 122.
As shown in
Side end portion 85 is provided with a recessed portion 83. Recessed portion 83 has a shape recessed in the direction toward bottom plate 60 in a side view. Recessed portion 83 is provided to extend across both the front and rear sides with respect to second reference straight line 122. Recessed portion 83 is provided at a position other than the position of side cutter 77.
As shown in
Recessed portion 83 includes a second deepest portion 84. At second deepest portion 84, length h from first reference straight line 121 to recessed portion 83 has a maximum value (hmax). Second deepest portion 84 is recessed most in recessed portion 83 with respect to first reference straight line 121.
Second deepest portion 84 is located on second reference straight line 122. In this case, hmax corresponds to the length of second reference straight line 122 from first reference straight line 121 to second deepest portion 84. In the linear direction along first reference straight line 121, length h from first reference straight line 121 to recessed portion 83 is decreased from second deepest portion 84 toward the front side and decreased from second deepest portion 84 toward the rear side.
Bottom plate 60 has a curved shape having a curvature 1/R (a radius of curvature R) in first deepest portion 62. Recessed portion 83 has a curved shape having a curvature 1/r (a radius of curvature r) in second deepest portion 84. Curvature 1/r of recessed portion 83 in second deepest portion 84 is equal to or greater than curvature 1/R of bottom plate 60 in first deepest portion 62 (1/r≥1/R). Curvature 1/r of recessed portion 83 in second deepest portion 84 may be smaller than curvature 1/R of bottom plate 60 in first deepest portion 62 (1/r<1/R).
In
First, the tip end of tooth 76 is brought into contact with the ground surface (bucket 50A). Then, bucket 50 is operated to pivot about center axis 110, to thereby cause bucket 50 to penetrate into the ground while tooth 76 is positioned as a leading edge (bucket 50B). Then, while bucket 50 is operated to pivot about center axis 110, boom 16 and arm 17 are operated to pivot to thereby move bucket 50 horizontally in the direction toward cab 14 (bucket 50C). Then, bucket 50 in which excavated soil is loaded is raised from the ground surface.
As a typical example, while bucket 50 moves horizontally as shown by bucket 50C in
In this case, in bucket 50, angle β formed between second reference straight line 122 and front lip 72 is smaller than angle α formed between second reference straight line 122 and first inclined portion 67, with the result that the angle formed between front lip 72 and the moving direction of bucket 50 can be set smaller. Thereby, when front lip 72 and the front side of bottom plate 60 are moved through the underground, soil can be efficiently moved into bucket 50 through front lip 72, as indicated by an arrow 141. Furthermore, length Lb of first reference straight line 121 from intersection point P between first reference straight line 121 and second reference straight line 122 to tip end 73 of front lip 72 is shorter than length La from intersection point P between first reference straight line 121 and second reference straight line 122 to center axis 110. Thereby, first deepest portion 62 of bottom plate 60 that is located on second reference straight line 122 is located closer to front lip 72 in the linear direction along first reference straight line 121, with the result that the soil loaded into bucket 50 is more readily moved from front lip 72 toward first deepest portion 62.
On the other hand, on the ground above the ground surface, as indicated by a solid line 133 in
For the reasons as described above, the amount of soil loaded into bucket 50 can be increased, thereby allowing more efficient excavation.
The relation between the inclination of first inclined portion 67 and angle of repose δ formed by the soil having a shape bulging from the ground surface will be hereinafter described. Specifically, when first inclined portion 67 is inclined at an angle excessively larger than angle of repose δ, region 52 may not be entirely filled with soil. As a result, when bucket 50 is raised from the ground surface, a dead space not filled with soil may be formed inside bucket 50. Furthermore, when first inclined portion 67 is inclined at an angle excessively smaller than angle of repose δ, the resistance received from first inclined portion 67 may prevent soil from being efficiently moved into region 52.
For addressing the above-described situations, angle α formed between second reference straight line 122 and first inclined portion 67 is set to fall within a range exceeding 20° and equal to or less than 45°, and further preferably a range equal to or greater than 30° and equal to or less than 40°. Thereby, first inclined portion 67 can be inclined at an angle close to angle of repose δ. Thus, the amount of soil loaded into bucket 50 can be increased, so that the above-mentioned effect of allowing efficient excavation can be more effectively achieved.
Furthermore, in bucket 50, angle γ formed between second reference straight line 122 and second inclined portion 68 is smaller than the angle formed between second reference straight line 122 and first inclined portion 67. Thereby, soil is moved also into region 53 inside bucket 50 directly below second inclined portion 68 such that region 53 is entirely filled with soil. Thereby, formation of a dead space inside bucket 50 can be more reliably prevented.
When bucket 50 is caused to penetrate into the ground, side plate 81 needs to push away soil so as to dig into the ground. In this case, side plate 81 may increase the resistance caused during penetration of bucket 50 (penetration resistance). For addressing such a situation, side end portion 85 of side plate 81 is provided with recessed portion 83, so that the length of a portion of side plate 81 that digs into the ground can be reduced. This can suppress an increase in penetration resistance resulting from side plate 81, to thereby allow an improvement in penetration performance of bucket 50 into the ground.
Since the length of side plate 81 in the up-down direction is maximum at a position on second reference straight line 122 that passes through first deepest portion 62 of bottom plate 60, side plate 81 on second reference straight line 122 most significantly influences an increase in penetration resistance. For addressing such a situation, recessed portion 83 includes second deepest portion 84 on second reference straight line 122, so that the length of side plate 81 on second reference straight line 122 can be further reduced. Thereby, the above-mentioned effect of suppressing an increase in penetration resistance resulting from side plate 81 can be more effectively achieved. In addition, it becomes possible to suppress an excessive change in magnitude of the penetration resistance resulting from side plate 81 between the time when side plate 81 on second reference straight line 122 penetrates into the ground, and the time when side plate 81 at the position displaced from second reference straight line 122 in the front-rear direction penetrates into the ground. Thereby, the operation of excavating soil can be more smoothly performed.
Furthermore, curvature 1/r of second deepest portion 84 is equal to or greater than curvature 1/R of first deepest portion 62. By the configuration as described above, recessed portion 83 in second deepest portion 84 can be more largely recessed, with the result that the length of side plate 81 on second reference straight line 122 that passes through first deepest portion 62 can be further more effectively reduced. Thereby, the penetration performance of bucket 50 into the ground can be further improved.
Also, curvature 1/r of second deepest portion 84 may be equal to or less than curvature 1/R of first deepest portion 62. In this case, it becomes possible to effectively suppress an increase in penetration resistance resulting from side plate 81 in a wider range of the position displaced from second reference straight line 122 in the front-rear direction.
The following is a summarized explanation about the configuration and the effect of bucket 50 and hydraulic excavator 100 in the present embodiment.
Bucket 50 is coupled to arm 17 of work implement 12 to be pivotable about center axis 110 as a prescribed axis. Bucket 50 includes bottom plate 60, a pair of side plates 81, bracket 86, and front lip 72. Bottom plate 60 faces opening 51 of bucket 50. The pair of side plates 81 is disposed to face each other on both sides of bottom plate 60. Bracket 86 is provided on the back surface of bottom plate 60. Bracket 86 is coupled to arm 17 on center axis 110. Front lip 72 is provided along opening 51. Bottom plate 60 includes first inclined portion 67 on the side where bracket 86 is attached. Bottom plate 60 further includes first deepest portion 62 as the deepest portion. At first deepest portion 62, the length from first reference straight line 121 to bottom plate 60 is maximum. First reference straight line 121 passes through center axis 110 and tip end 73 of front lip 72. Angle β formed between front lip 72 and second reference straight line 122, which is orthogonal to first reference straight line 121 and passes through first deepest portion 62, is smaller than angle α formed between second reference straight line 122 and first inclined portion 67. Intersection point P between first reference straight line 121 and second reference straight line 122 is located close to front lip 72 on first reference straight line 121.
According to the configuration as described above, angle β formed between second reference straight line 122 and front lip 72 is smaller than angle α formed between second reference straight line 122 and first inclined portion 67. Thereby, the excavated soil can be efficiently moved into bucket 50 through front lip 72. Also, intersection point P between first reference straight line 121 and second reference straight line 122 is located close to front lip 72 on first reference straight line 121. Thereby, the soil loaded into bucket 50 is more readily moved from front lip 72 toward first deepest portion 62. Furthermore, angle α formed between second reference straight line 122 and first inclined portion 67 is larger than angle β formed between second reference straight line 122 and front lip 72. Thereby, soil can be efficiently moved into region 52 directly below first inclined portion 67.
Accordingly, the amount of soil to be loaded into bucket 50 can be increased, thereby allowing efficient excavation.
Furthermore, the angle formed between second reference straight line 122 and first inclined portion 67 is in a range exceeding 20° and equal to or less than 45°. Also, the angle formed between second reference straight line 122 and first inclined portion 67 is in a range equal to or greater than 30° and equal to or less than 40°.
According to the configuration as described above, first inclined portion 67 can be inclined at an angle closer to angle of repose δ of the soil having a shape bulging from the ground surface. Thereby, soil can be more efficiently moved into region 52 directly below first inclined portion 67.
Also, bottom plate 60 further includes second inclined portion 68. Second inclined portion 68 is contiguous to first inclined portion 67. Second inclined portion 68 is provided along opening 51. Angle γ formed between second reference straight line 122 and second inclined portion 68 is smaller than angle α formed between second reference straight line 122 and first inclined portion 67.
According to the configuration as described above, soil can be moved into region 53 directly below second inclined portion 68 such that region 53 is entirely filled with the soil. This can prevent formation of a dead space inside bucket 50 when bucket 50 is raised.
Furthermore, side plate 81 includes side end portion 85. Side end portion 85 defines the opening edge of opening 51. Side end portion 85 is provided with recessed portion 83. In a side view seen in the axial direction of center axis 110, recessed portion 83 is recessed in the direction toward bottom plate 60.
The configuration as described above can suppress an increase in penetration resistance resulting from side plate 81, so that the penetration performance of bucket 50 into the ground can be improved.
Hydraulic excavator 100 includes vehicular body 11 and work implement 12. Work implement 12 is attached to vehicular body 11. Work implement 12 includes boom 16, arm 17, and bucket 50. Boom 16 is pivotably coupled to vehicular body 11. Arm 17 is pivotably coupled to boom 16. Bucket 50 is pivotably coupled to arm 17.
According to the configuration as described above, the amount of soil loaded into bucket 50 can be increased, thereby allowing more efficient excavation by hydraulic excavator 100.
As shown in
Bottom plate 60 includes first inclined portion 67. Bottom plate 60 does not include second inclined portion 68 in the first embodiment.
Also, an angle β formed between second reference straight line 122 and front lip 72 is smaller than an angle α formed between second reference straight line 122 and first inclined portion 67 (β<α). When angle α is in a range exceeding 20° and equal to or less than 45° (20°<α45°), angle β is in a range equal to or less than 20° (β≤20°.
Intersection point P between first reference straight line 121 and second reference straight line 122 is located close to front lip 72 on first reference straight line 121. A length Lb of first reference straight line 121 from intersection point P between first reference straight line 121 and second reference straight line 122 to tip end 73 of front lip 72 is shorter than a length La from intersection point P between first reference straight line 121 and second reference straight line 122 to center axis 110 (Lb<La).
According to the bucket in the second embodiment of the present disclosure configured as described above, the same effect as that in the first embodiment can be achieved.
As shown in
Bottom portion 61 of bottom plate 60 has a curved shape on the front side with respect to second reference straight line 122. Bottom portion 61 has a bent shape formed by connection of two straight lines at different inclinations on the rear side with respect to second reference straight line 122. First deepest portion 62 of bottom plate 60 forms a corner portion protruding downward.
Second deepest portion 84 of recessed portion 83 is provided at the position displaced from second reference straight line 122 in the linear direction along first reference straight line 121. Second deepest portion 84 is provided on the front side with respect to second reference straight line 122 in the linear direction along first reference straight line 121. Second deepest portion 84 has a triangular cutout shape. A side lip 82 is not provided with side cutter 77 in the first embodiment.
An angle β formed between second reference straight line 122 and front lip 72 is smaller than an angle α formed between second reference straight line 122 and first inclined portion 67 (β<α). When angle α is in a range exceeding 20° and equal to or less than 45° (20°<α≤45°), angle β is in a range equal to or less than 20° (β≤20°). When angle α is in a range equal to or greater than 30° and equal to or less than 40° (30°≤α≤40°), angle β is in a range less than 30°. The sum of angle α and angle β is in a range exceeding 50° and equal to or less than 60° (50°<α+β≤60°).
Intersection point P between first reference straight line 121 and second reference straight line 122 is located close to front lip 72 on first reference straight line 121. Length Lb of first reference straight line 121 from intersection point P between first reference straight line 121 and second reference straight line 122 to tip end 73 of front lip 72 is shorter than length La from intersection point P between first reference straight line 121 and second reference straight line 122 to center axis 110 (Lb<La).
According to the bucket in the third embodiment of the present disclosure configured as described above, the same effect as that in the first embodiment can be achieved.
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 scope of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the scope of the claims.
The present disclosure is applicable to a bucket mounted in a work vehicle.
Number | Date | Country | Kind |
---|---|---|---|
2018-168690 | Sep 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2019/035294 | 9/9/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/054640 | 3/19/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4081919 | Teach | Apr 1978 | A |
4449309 | Hemphill | May 1984 | A |
6834447 | Currey | Dec 2004 | B1 |
8707589 | Hilton | Apr 2014 | B2 |
8851826 | Nagata | Oct 2014 | B2 |
9617709 | Shintani | Apr 2017 | B2 |
20050268500 | Imamura et al. | Dec 2005 | A1 |
20130323000 | Rochel et al. | Dec 2013 | A1 |
20160251821 | Yoshida et al. | Sep 2016 | A1 |
20170016203 | Honda | Jan 2017 | A1 |
20170350091 | Worth | Dec 2017 | A1 |
Number | Date | Country |
---|---|---|
103857843 | Jun 2014 | CN |
105339557 | Feb 2016 | CN |
H05-067654 | Sep 1993 | JP |
H06-020546 | Mar 1994 | JP |
2002-054171 | Feb 2002 | JP |
2006-188870 | Jul 2006 | JP |
3982584 | Sep 2007 | JP |
2010-53590 | Mar 2010 | JP |
2013-217067 | Oct 2013 | JP |
100980483 | Sep 2010 | KR |
WO-2004023001 | Mar 2004 | WO |
WO-2014171024 | Oct 2014 | WO |
Number | Date | Country | |
---|---|---|---|
20210317631 A1 | Oct 2021 | US |