The present invention relates to a work machine.
Priority is claimed on Japanese Patent Application No. 2019-111371, filed Jun. 14, 2019, the content of which is incorporated herein by reference.
Patent Document 1 discloses an electric excavator as an example of a work machine. The electric excavator includes an undercarriage and an upper swing body. The upper swing body is provided with a boom, an arm, and a bucket (work tool). The boom, arm, and bucket are driven by an electric motor and an electric cylinder.
In such a work machine, the electric motor provided in the boom is provided so as to be exposed to the outside of the boom. Therefore, the electric motor may receive an impact from the outside.
The present invention has been made in view of such a problem and the object is to provide a work machine having high reliability.
The present invention according to one aspect of the work machine includes: a vehicle main body; a boom that has a base end portion supported by the vehicle main body and that extends from the vehicle main body; a first actuator that connects the boom and the vehicle main body and is configured to rotate the boom with respect to the vehicle main body about a first central axis intersecting with an extending direction of the boom; and a first electric motor that is connected to the first actuator to operate the first actuator, wherein the boom comprises: a pair of boom lateral plates that is disposed to face each other in a direction of the first central axis; and a boom bottom plate that connects the boom lateral plates to each other, wherein the first electric motor is disposed in a boom internal space surrounded by the pair of boom lateral plates and the boom bottom plate.
According to the work machine of the above aspect, it is possible to avoid an impact on the electric motor, and high reliability is achieved.
Hereinafter, the embodiment of present invention will be described in detail with reference to
<Excavator (Work Machine)>
As shown in the
<Vehicle Main Body>
The vehicle main body 110 includes an undercarriage 121 and an upper swing body 111. Hereinafter, a direction in which gravity acts in a state in which the excavator 100 is disposed in a horizontal surface is referred to as a “vertical direction”.
The undercarriage 121 has a pair of right and left crawler belts 122. For example, the undercarriage 121 is capable of traveling by driving the crawler belts 122 by an electric motor (not shown). A hydraulic motor may be used instead of the electric motor. On a front portion of the undercarriage 121, a blade 123 as a dump plate extending in a vehicle width direction of the undercarriage 121 (hereinafter, simply referred to as a “width direction”) is provided. A height position of the blade 123 is capable of being adjusted using, for example, an electric actuator.
The upper swing body 111 is the upper portion of undercarriage 121. In the upper swing body 111, the above-described electric motor for traveling, and a battery and an inverter serving as a power source of the electric motor for traveling are installed. The upper swing body 111 is capable of swinging about an axis extending in the vertical direction with respect to the undercarriage 121.
The upper swing body 111 is provided with a canopy 112. The canopy 112 forms a driving space CA. That is, the canopy 112 includes: a hood 113 that forms a ceiling portion of the driving space CA; a rear support 114 that is provided on a rear portion of the hood 113 and that extends downward from the hood 113; and a front support 115 that is provided on a front portion of the hood 113 and that extends downward from the hood 113. A pair of the front supports 115 and a pair of the rear supports 114 are each provided at positions separated from each other in the width direction.
Here, regardless of a traveling direction of the undercarriage 121, a front and rear of an operator is referred to as “forward-rearward directions” of the upper swing body 111. The vehicle width direction intersecting the forward-rearward directions is referred to as a “width direction”.
As shown in
<Boom>
As shown in
<Boom Support Portion>
As shown in
<Boom Lateral Plate>
As shown in
The base end portion 12x of the pair of boom lateral plates 12 are provided integrally with the boom support portion 14, so that each boom lateral plate 12 extends so as to separate from the boom support portion 14.
<Arm Support Portion>
As shown in
As shown in
<Boom Bottom Plate>
The boom bottom plate 13 has a plate shape as shown in
As shown in
As shown in
The upper surface 18b of the tip end convex portion 18 is disposed on a side closer to the boom bottom plate 13 than an upper edge portion of the boom lateral plate 12, that is, an edge portion on a side away from the boom bottom plate 13 in the first direction D1. As a result, a tip end-side space TS1 is formed on the first direction D1 side of the upper surface 18b by being sandwiched by the upper surface 18b of the tip end convex portion 18 and the pair of boom lateral plates 12. In the tip end convex portion 18, a passage 18c penetrating in an extending direction of the boom 1 and opening to an inclination surface 18a is provided at a position adjacent to one boom lateral plate 12.
Further, from the boom bottom plate 13, a base end convex portion 19 is provided which protrudes in the first direction D1 on the base end portion 12x side of the boom lateral plate 12 and connects the pair of boom lateral plates 12 to each other. Therefore, the base end convex portion 19 is provided on the boom bottom plate 13 so as to be sandwiched by the pair of boom lateral plates 12.
As shown in
Here, a space that is surrounded by the boom bottom plate 13 and the pair of boom lateral plates 12 and that is formed on the first direction D1 side of the boom bottom plate 13 between the inclination surface 18a of the tip end convex portion 18 and the inclination surface 19a of the base end convex portion 19 is defined as a boom internal space S1. The boom internal space S1 is disposed at a central portion in the extending direction Da of the boom lateral plate 12.
<Boom Partition Member>
The boom partition member 17 has a plate shape as shown in
The first actuator hole 12a is provided closer to the base end portion 12x side of the boom lateral plate 12 than the second actuator hole 12b. Central axes of the first actuator hole 12a and the second actuator hole 12b are provided in parallel with central axes of the first through hole 14a and the second through hole 16a.
<Arm>
As shown in
<Arm Lateral Plate>
As shown by
As shown in
In each arm lateral plate 21, a size in a vertically provided direction from the arm bottom plate 22 (a plate width size) gradually increases from a position where the actuator connection hole 21b of the base end portion 21x is provided toward the tip end portion 21y, and then gradually decreases. The boom connection hole 21a and the third actuator hole 21c are provided at a position where the plate width size is the largest in the arm lateral plate 21.
As shown in
<Work Tool Support Portion>
As shown in
<Arm Bottom Plate>
The arm bottom plate 22 has a flat plate shape as shown in
As shown in
As shown in
Here, a space that is surrounded by the arm bottom plate 22 and the pair of arm lateral plates 21 and formed on the second direction D2 side of the arm bottom plate 22 between the inclination surface 26a of the tip end convex portion 26 and the arm partition member 24 is referred to as an arm internal space S2.
<Arm Partition Member>
The arm partition member 24 has a plate shape as shown in
<Bucket>
The bucket 3 as the work tool is provided with a work tool through hole 31a penetrating in the width direction of the upper swing body 111 as shown in
The third pin P3 is inserted into the work tool through hole 31a together with the third through hole 23a of the work tool support portion 23 in the arm 2; thereby the bucket 3 is supported so as to be rotatable about the third central axis O3 with respect to the arm 2.
<First Actuator>
The first actuator 4 has a rod shape that expands and contracts along an extending direction of the boom 1 as shown in
A second end of the first actuator 4 is connected to the first actuator hole 12a of the boom 1 by a pin Pb, and is supported by the boom 1 so as to be rotatable about a central axis extending in the width direction of the upper swing body 111 with respect to the boom 1. As a result, the first actuator 4 is disposed closer to the base end portion 12x side of the boom lateral plate 12 than the boom partition member 17.
<First Electric Motor>
The first electric motor 5 is provided adjacent to the first actuator 4 as shown in
In the present embodiment, the first electric motor 5 is disposed at a position closer to the boom bottom plate 13 than the first actuator 4, and is disposed between the boom bottom plate 13 and the first actuator 4. The first electric motor 5 is disposed in the boom internal space S1. A first power transmission mechanism 41 using, for example, a planetary gear mechanism or a pulley is provided between the first electric motor 5 and the first actuator 4.
In the present embodiment, the first power transmission mechanism 41 is provided at the second end of the first actuator 4, and the first electric motor 5 is disposed on the second end side of the first actuator 4. A wiring 42 extends from the first electric motor 5. The wiring 42 extends along the inclination surface 19a and the upper surface 19b of the base end convex portion 19 of the boom 1, and is connected to a power source (not shown) provided in the upper swing body 111 through an inside of the bracket 130. Therefore, the wiring 42 is disposed in the boom internal space S1 and the base end-side space PS1. Here, the first electric motor 5 is always disposed in the boom internal space S1 regardless of a posture of the boom 1. The first electric motor 5 and the wiring 42 are disposed closer to the base end portion 12x side of the boom lateral plate 12 than the boom partition member 17.
<Second Actuator>
The second actuator 6 has a configuration similar to that of the first actuator 4 as shown in
A second end of the second actuator 6 is connected to the actuator connection hole 21b of the arm 2 by a pin Pd, and is supported by the arm 2 so as to be rotatable around a central axis extending in the width direction of the upper swing body 111 with respect to the arm 2. Thus, the second actuator 6 is disposed closer to the tip end portion 12y side of the boom lateral plate 12 than the boom partition member 17.
<Second Electric Motor>
The second electric motor 7 has a configuration similar to that of the first electric motor 5, is provided adjacent to the second actuator 6 as shown in
In the present embodiment, the second electric motor 7 is disposed at a position closer to the boom bottom plate 13 than the second actuator 6, and is disposed between the boom bottom plate 13 and the second actuator 6. The second electric motor 7 is disposed in the boom internal space S1. A second power transmission mechanism 44 is provided between the second electric motor 7 and the second actuator 6. The second power transmission mechanism 44 has the same configuration as the first power transmission mechanism 41.
In the present embodiment, the second power transmission mechanism 44 is provided at the first end of the second actuator 6, and the second electric motor 7 is disposed on the first end side of the second actuator 6. A wiring 45 extends from the second electric motor 7. The wiring 45 extends toward the first electric motor 5 along the inclination surface 19a and the upper surface 19b of the base end convex portion 19 of the boom 1 together with the wiring 42 of the first electric motor 5, and is connected to a power source (not shown) provided in the upper swing body 111 through the inside of the bracket 130. Therefore, the wiring 45 is disposed in the boom internal space S1 and the base end-side space PS1. Here, the second electric motor 7 is always disposed in the boom internal space S1 regardless of the posture of the arm 2. The second electric motor 7 and the wiring 45 are disposed closer to the tip end portion 12y side of the boom lateral plate 12 than the boom partition member 17, and the second electric motor 7 and the first electric motor 5 are provided at positions close to each other in the boom internal space S1.
<Third Actuator>
As shown in
A first link member 51 is provided at a second end of the third actuator 8. A first link through hole 51a penetrating in the width direction of the upper swing body 111 is provided at the first end of the first link member 51. The second end of the third actuator 8 is connected to the first link through hole 51a by a pin Pf. Therefore, the third actuator 8 supports the first link member 51 so as to be rotatable about a central axis extending in the width direction of the upper swing body 111 with respect to the first link member 51.
The second end of the first link member 51 is provided with a second link through hole 51b penetrating in the width direction of the upper swing body 111. The second link through hole 51b is connected to the first link connection hole 25a of the arm 2 by a pin Pg. Therefore, the first link member 51 is supported by the arm 2 so as to be rotatable about the central axis extending in the width direction of the upper swing body 111 with respect to the arm 2.
The third actuator 8 is provided with a second link member 52. A third link through hole 52a penetrating in the width direction of the upper swing body 111 is provided at the first end of the second link member 52. The third link through hole 52a is connected to the second end of the third actuator 8 and the first link through hole 51a by a pin Pf. Therefore, the second link member 52 is provided so as to be rotatable about a central axis extending in the width direction of the upper swing body 111 with respect to the second end of the third actuator 8 and the first link member 51.
Further, the second end of the second link member 52 is provided with a fourth link through hole 52b penetrating in the width direction of the upper swing body 111. The fourth link through hole 52b is connected to the second link connection hole 31b of the bucket 3 by a pin Ph. Therefore, the second link member 52 is provided so as to be rotatable about a central axis extending in the width direction of the upper swing body 111 with respect to the bucket 3. The third actuator 8 is disposed closer to the tip end portion 21y side of the arm lateral plate 21 than the arm partition member 24.
<Third Electric Motor>
The third electric motor 9 has the same configuration as the first electric motor 5 and the second electric motor 7, is provided adjacent to the third actuator 8 as shown in
In the present embodiment, the third electric motor 9 is disposed at a position closer to the arm bottom plate 22 than the third actuator 8, and is disposed between the arm bottom plate 22 and the third actuator 8. The third electric motor 9 is disposed in the arm internal space S2. A third power transmission mechanism 47 is provided between the third electric motor 9 and the third actuator 8. The third power transmission mechanism 47 has the same configuration as the first power transmission mechanism 41 and the second power transmission mechanism 44.
In the present embodiment, the third power transmission mechanism 47 is provided at the first end of the third actuator 8, and the third electric motor 9 is disposed on the first end side of the third actuator 8. A wiring 48 extends from the third electric motor 9. The wiring 48 extends toward the boom 1 and passes through a passage 18c shown in
<Operation and Effects>
In the excavator 100 having the above-described configuration, the first electric motor 5 is disposed in the boom internal space S1. That is, the first electric motor 5 is provided so as to be surrounded between the pair of boom lateral plates 12 and boom bottom plate 13. Therefore, the first electric motor 5 is not exposed from the boom 1.
As a result, it is possible to prevent the first electric motor 5 from receiving an impact when the excavator 100 is performing work, to continue the work, and to stably operate the excavator 100. Therefore, the reliability of the excavator 100 is improved.
Similarly, the second electric motor 7 is disposed in the boom internal space S1. Therefore, the second electric motor 7 is not exposed from the boom 1, and it is possible to prevent the second electric motor 7 from receiving an impact when the excavator 100 is performing work, thus improving the reliability of the excavator 100.
The third electric motor 9 is disposed in the arm internal space S2. That is, the third electric motor 9 is provided so as to be surrounded between the pair of arm lateral plates 21 and the arm bottom plate 22. Therefore, the third electric motor 9 is not exposed from the arm 2, and it is possible to prevent the third electric motor 9 from receiving an impact when work is performed by the excavator 100, thus improving the reliability of the excavator 100.
Since the first electric motor 5 is disposed between the boom bottom plate 13 and the first actuator 4, the first electric motor 5 can be protected by the first actuator 4. As a result, an impact on the first electric motor 5 can be further avoided.
Similarly, since the second electric motor 7 is disposed between the boom bottom plate 13 and the second actuator 6, the second electric motor 7 can be protected by the second actuator 6. As a result, an impact on the second electric motor 7 can be further avoided.
Since the third electric motor 9 is disposed between the arm bottom plate 22 and the third actuator 8, the third electric motor 9 can be protected by the third actuator 8. As a result, an impact on the third electric motor 9 can be further avoided.
In addition, the first electric motor 5 and the second electric motor 7 are both disposed in the boom internal space S1. As a result, the first electric motor 5 and the second electric motor 7 are provided so as to be close proximity in the central portion in the extending direction of the boom 1. Therefore, maintenance of the first electric motor 5 and the second electric motor 7 can be performed in one place, and maintainability can be improved.
Further, since the boom partition member 17 is provided so as to connect the pair of boom lateral plates 12, the strength of the boom 1 can be improved. That is, the vertically provided size of the boom lateral plate 12 from the boom bottom plate 13 (the size in the first direction D1) is the largest at the central portion in the extending direction Da; however, deflection of the boom lateral plate 12 can be suppressed by providing the boom partition member 17 at that position.
Similarly, since the arm partition member 24 is provided so as to connect the pair of arm lateral plates 21, the strength of the arm 2 can be improved.
Although the embodiment of the present invention has been described above, the present invention is not limited thereto and can be appropriately changed without departing from the technical idea of the invention.
For example, the boom 1 may further include a top plate disposed to face the boom bottom plate 13 and connecting the pair of boom lateral plates 12 to each other. In this case, the boom 1 has a box shape with a cover, and the boom internal space S1 is surrounded by the boom bottom plate 13, the boom lateral plates 12, and the top plate, on the left, right, top and bottom thereof. In this case, since the first electric motor 5 and the second electric motor 7 are also surrounded from the vertically provided direction of the boom lateral plate 12, it is possible to further avoid an impact on the first electric motor 5 and the second electric motor 7.
Similarly, the arm 2 may further include a top plate disposed to face the arm bottom plate 22 and connecting the pair of arm lateral plates 21 to each other. In this case, the arm 2 has a box shape with a cover, and the arm internal space S2 is surrounded by the boom bottom plate 13, the boom lateral plates 12, and the top plate, on the left, right, top and bottom thereof. In this case, since the third electric motor 9 is also surrounded from the vertically provided direction of the arm lateral plate 21, it is possible to further avoid an impact on the third electric motor 9.
The position of the first electric motor 5 and the position of the first actuator 4 may be reversed. That is, the first actuator 4 may be provided so as to be sandwiched between the first electric motor 5 and the boom bottom plate 13. The position of the second electric motor 7 and the position of the second actuator 6 may be reversed, and the position of the third electric motor 9 and the position of the third actuator 8 may be reversed. The third electric motor 9 may be exposed from the arm 2.
In embodiment, the excavator 100 has been described as an example of a work machine, but the present invention is not limited thereto. For example, the invention according to the present embodiment may be applied to a crane or a pipe layer that does not include the arm 2. In addition, although an example in which the bucket 3 is provided in the arm 2 has been described as an example of the work tool, the invention according to the present embodiment may be applied to the excavator 100 in which a crushing tool, a cutting machine, or the like is provided in the arm 2 instead of the bucket 3.
According to the work machine of present invention, an impact to the electric motor can be avoided and high reliability is achieved.
Number | Date | Country | Kind |
---|---|---|---|
2019-111371 | Jun 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2020/023226 | 6/12/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/251023 | 12/17/2020 | WO | A |
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Number | Date | Country | |
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20210381193 A1 | Dec 2021 | US |