JP2024044839A - work equipment - Google Patents

Abstract

[Problem] To improve workability. [Solution] In a belt sander 10, a reinforcing portion 90 is provided on a side housing 24, and the reinforcing portion 90 protrudes from the side housing 24 to one axial side of a motor pulley 54 and a transmission pulley 56. Specifically, the reinforcing portion 90 extends along an overhead line L, protrudes from the side housing 24 to the left, and is formed in a concave shape (U-shape) that is open to the right when viewed from the longitudinal direction. Therefore, the side housing 24 can be reinforced by the reinforcing portion 90. Therefore, compared to a case in which the reinforcing portion 90 is omitted in the side housing 24, the bending rigidity of the side housing 24 in the left-right direction can be increased. As a result, the belt sander 10 can be operated well while maintaining a good support state of the motor pulley 54 and the transmission pulley 56 by the side housing 24. [Selected Figure] Fig. 5

Description

The present invention relates to a working machine.

The belt sander (work machine) described in Patent Document 1 below employs a transmission mechanism using a belt as a mechanism for transmitting the driving force of a motor. Specifically, the transmission mechanism includes a first pulley, a second pulley, and a belt that is passed around the first pulley and the second pulley, and the first pulley is driven by the driving force of the motor. Rotate.

Japanese Patent Application Publication No. 2008-207295

Here, in the transmission mechanism using a belt, the tension of the belt acts on the member supporting the first pulley and the second pulley via the first pulley and the second pulley. Specifically, an inward force in the longitudinal direction of the belt acts on the support member. At this time, if the support member is deformed by the force acting on the support member, there is a possibility that the support performance for the belt will be reduced and the workability of the belt sander will be reduced. Another problem is that when a belt sander is provided with a dust collection function, static electricity generated by the dust may affect workability.

Taking the above into consideration, the present invention aims to provide a work machine that can improve workability.

One or more embodiments of the present invention are a work machine including a power transmission mechanism including a first pulley, a second pulley, and a belt stretched between the first pulley and the second pulley, a support member supporting the first pulley and the second pulley, and a reinforcing part provided on the support member, protruding in the axial direction of the first pulley, and extending along an imaginary line connecting the axis of the first pulley and the axis of the second pulley when viewed from the axial direction.

In one or more embodiments of the present invention, the power transmission mechanism includes a motor and a fan that rotates when driven by the motor to generate an air flow, the support member includes a passage through which the air flow passes, and the passage is expanded by the reinforcing part.

One or more embodiments of the present invention are a work machine having a processing unit that operates by the driving force transmitted from the power transmission mechanism to process the workpiece, and the air flow is a dust-collecting wind for collecting dust generated during processing.

In one or more embodiments of the present invention, the first pulley, the second pulley, and the belt are located on one side of the support member in the axial direction, and the reinforcing portion is The working machine protrudes from the member to one side in the axial direction, and the reinforcing portion is located between the first pulley and the second pulley and inside the belt when viewed from the axial direction. be.

In one or more embodiments of the present invention, the first pulley and the fan are mounted on the drive shaft of the motor so as to be rotatable together, the fan is located inside the passage, and the reinforcing part is formed in a concave shape that is open toward the passage when viewed from the longitudinal direction.

In one or more embodiments of the present invention, the outer diameter of the second pulley is set to be larger than the outer diameter of the first pulley, and the reinforcing portion gradually or stepwise expands toward the second pulley in a direction perpendicular to both the axial direction and the extension direction of the overhead wire.

One or more embodiments of the present invention is a working machine in which the support member is provided with a guide mechanism that guides the flow of the airflow.

In one or more embodiments of the present invention, the motor is housed in a housing with the left-right direction as the axial direction, the housing has a suction chamber that draws in air outside the housing by the air flow, the support member is assembled to the housing from one side in the left-right direction, the passage is connected to the suction chamber, a fan housing section that houses the fan is provided at one end of the passage in the front-rear direction, and the guide mechanism section is a work machine having a first guide section that extends in the front-rear direction and guides the air flow toward the fan.

One or more embodiments of the present invention is a working machine in which the first front guide section constitutes a lower wall of the passage section.

One or more embodiments of the present invention are a working machine in which the first guide portion intersects with a longitudinally intermediate portion of the reinforcing portion when viewed from the left and right.

In one or more embodiments of the present invention, the first pulley and the second pulley are configured to be rotatable about the left-right direction, and the reinforcing portion protrudes from the support member to one side in the left-right direction. The guide mechanism section includes a second guide section provided in the reinforcing section, and is a working machine that guides the airflow to the other side in the left-right direction by the second guide section.

One or more embodiments of the present invention are a work machine in which the second guide section is located in the fan housing section.

In one or more embodiments of the present invention, the processing unit is a work machine including a drive pulley that rotates by the driving force transmitted from the power transmission mechanism, a driven pulley that is arranged parallel to the drive pulley, and a grinding belt that is stretched between the drive pulley and the driven pulley and rotates in the circumferential direction as the drive pulley rotates.

In one or more embodiments of the present invention, a cover member that covers the first pulley, the second pulley, and the belt is attached to the support member, and a portion of the cover member is disposed adjacent to the reinforcement portion in the protruding direction of the reinforcement portion.

In one or more embodiments of the present invention, at least a portion of the reinforcing portion overlaps the first pulley, the second pulley, or the belt when viewed in a direction perpendicular to the axial direction. This is a work machine configured as follows.

According to one or more embodiments of the present invention, workability can be improved.

It is a top view showing the belt sander concerning this embodiment seen from the upper side. FIG. 2 is a side view of the belt sander shown in FIG. 1 as seen from the left side. FIG. 2 is a side view of the belt sander shown in FIG. 1 as seen from the right side. 4 is a cross-sectional view seen from the right side showing a state in which a machined recess of a main housing shown in FIG. 3 communicates with a suction chamber. FIG. 3 is a side view showing the periphery of a side housing of the belt sander shown in FIG. 2 with a belt cover removed. FIG. 6 is a cross-sectional view (cross-sectional view taken along line 6-6 in FIG. 1 ) showing the inside of the side housing shown in FIG. 1 as seen from the left side. 7 is a perspective view showing the side housing shown in FIG. 6, as viewed diagonally from the front right. 8 is a cross-sectional view (cross-sectional view taken along line 8-8 in FIG. 2) showing the inside of the belt sander shown in FIG. 2 from above. FIG. 5 is a cross-sectional view (cross-sectional view taken along the line 9-9 in FIG. 4) seen from above, showing a state of communication between the suction chamber of the main body housing and the dust collection air passage section of the side housing shown in FIG. 4; 10 is a cross-sectional view (cross-sectional view taken along line 10-10 in FIG. 2) seen from the rear side, showing a state in which the belt cover shown in FIG. 2 is assembled to a side housing. 9 is a cross-sectional view corresponding to FIG. 8 , showing an example in which the amount of protrusion of the reinforcing portion shown in FIG. 8 from the side housing is changed. It is a perspective view seen diagonally from the left front with the belt cover and side housing removed.

Hereinafter, a belt sander 10 as a working machine according to the present embodiment will be explained using the drawings. Note that arrow UP, arrow FR, and arrow LH shown appropriately in the drawings indicate the upper side, front side, and left side of the belt sander 10. In the following description, when the directions are described using the up-down, front-back, and left-right directions, unless otherwise specified, the up-down direction, front-back direction, and left-right direction of the belt sander 10 are meant.

As shown in FIGS. 1 to 3 and 8, the belt sander 10 is configured as an electric tool that performs polishing or the like on a workpiece. The belt sander 10 includes a housing 20, a power transmission mechanism 40, a drive pulley 66 and a driven pulley 72 as processing parts, and a belt cover 80 as a cover member. The belt sander 10 also includes a reinforcing portion 90 for increasing the bending rigidity of the side housing 24 in the housing 20. Each configuration of the belt sander 10 will be described below.

(About the housing 20)
As shown in FIGS. 1 to 4, the housing 20 constitutes the outer shell of the belt sander 10. The housing 20 includes a main body housing 22 as a housing portion, and a side housing 24 as a support member that constitutes the left end portion of the housing 20.

(About the main body housing 22)
The main body housing 22 is constituted by housing members divided in the left-right direction, and the main body housing 22 is formed by assembling the housing members together. The main body housing 22 is formed into a hollow substantially rectangular parallelepiped box shape with a thickness direction in the up-down direction and a longitudinal direction in the front-rear direction. A processed recess 22A (see FIGS. 3 and 4) is formed at the lower end of the main body housing 22 to accommodate a drive pulley 66, a driven pulley 72, and an abrasive belt 78, which will be described later. It is formed in a concave shape that is open to the bottom and right side. A belt support portion 22B that supports the abrasive belt 78 is provided at the intermediate portion of the processing recess 22A in the front-back direction, and the belt support portion 22B (see FIGS. 3 and 4) extends from the left side of the processing recess 22A to the right It stands out. The lower surface of the belt support portion 22B is formed along a plane perpendicular to the up-down direction.

At the rear of the main body housing 22, a controller housing section 22C is provided above the machining recess 22A. As shown in Figs. 6, 8, and 9, a suction chamber 22D for suctioning dust generated during polishing is provided at the bottom of the controller housing section 22C, and the suction chamber 22D is formed in a concave shape that is open to the left. The rear end of the suction chamber 22D is configured as a suction port section 22D1 (see Figs. 4 and 9) that is open to the rear, and the suction chamber 22D and the machining recess 22A are connected by the suction port section 22D1. Specifically, the rear wall of the machining recess 22A is formed in an approximately C-shape that is open to the front in a side view, and the upper end of the rear wall is connected to the upper wall 22D2 of the suction chamber 22D (see Fig. 4). The right part of the front wall 22D3 of the suction chamber 22D extends in the left-right direction, and the left part of the front wall 22D3 of the suction chamber 22D is inclined forward as it approaches the left side in a plan view (see FIG. 9). The left end of the suction chamber 22D protrudes upward compared to the other parts and is open to the left (see FIGS. 6 and 10). The bottom wall 22D4 of the suction chamber 22D forms the upper wall of the machining recess 22A.

As shown in FIG. 10, a controller accommodation chamber 22E is formed in the upper part of the controller housing portion 22C. The controller accommodation chamber 22E is disposed adjacent to the right side of the left end of the suction chamber 22D, and a partition wall 22F is provided between the suction chamber 22D and the controller accommodation chamber 22E. A plurality of air intakes 22G are formed in the right wall of the controller accommodation chamber 22E. The controller 30 is accommodated in the controller accommodation chamber 22E, and the controller 30 is formed in a generally rectangular flat shape with the thickness direction being the up-down direction and the length direction being the front-rear direction.

As shown in Figures 1, 3, and 8, a motor housing portion 22H is provided at the front of the main body housing 22, above the machined recess 22A and in front of the suction chamber 22D and the controller housing chamber 22E. The motor housing portion 22H is formed in a generally bottomed cylindrical shape that is open to the left, and the upper portion of the motor housing portion 22H protrudes above the controller housing portion 22C. The right portion of the motor housing portion 22H and the right portion of the controller housing chamber 22E are in communication in the front-rear direction.

A battery 32 is detachably attached to the rear end of the main body housing 22 from above. The battery 32 supplies power to the controller 30 and a motor 42, which will be described later. A handle portion 22J is integrally provided at the upper portion of the main body housing 22. The handle portion 22J extends diagonally upward and forward from the rear end of the main body housing 22, and the front end of the handle portion 22J is bent downward and connected to the motor housing portion 22H. A knob portion 22K is provided at the front end of the handle portion 22J, and the knob portion 22K is formed into a substantially T-shape when viewed from above. Specifically, the knob portion 22K extends forward from the front end of the handle portion 22J, and the front end of the knob portion 22K protrudes outward in the left-right direction. A trigger 34 is provided at the front end of the handle portion 22J, and the trigger 34 protrudes downward from the handle portion 22J so that it can be pulled upward. A switch (not shown) is provided at the front end of the handle portion 22J, and when the trigger 34 is pulled, the switch is activated and outputs an on signal to the controller 30.

(About the side housing 24)
As shown in FIGS. 1, 2, and 5 to 10, the side housing 24 is made of resin. The side housing 24 is formed in the shape of a box with a relatively shallow bottom that is open to the right side, and extends along a direction that slopes upward toward the front side when viewed from the left side. The side housing 24 is disposed adjacent to the left side of the main body housing 22, is fastened and fixed to the main body housing 22, and closes off the motor housing portion 22H and the suction chamber 22D from the left side.

Inside the side housing 24, a first guide wall 24A is formed in the vertical middle as a first guide part constituting a guide mechanism part 92 for guiding the flow of the dust collection air W2 described later. The first guide wall 24A is formed in a substantially elongated plate shape extending in the front-rear direction with the vertical direction being the plate thickness direction, and protrudes to the right side from the bottom wall 24K (left wall) of the side housing 24. The bottom wall 24K is a flat plate part extending in the front-rear and up-down directions in the side housing 24. As a result, the inside of the side housing 24 is divided into upper and lower parts by the first guide wall 24A. The vertical position of the first guide wall 24A is approximately the same as the vertical position of the lower wall 22D4 of the suction chamber 22D in the main housing 22, and the upper part of the side housing 24 is configured as the dust collection air passage part 24B as a passage part. As a result, the lower wall of the dust collection air passage part 24B is configured by the first guide wall 24A, and the dust collection air passage part 24B is connected to the suction chamber 22D. The dust collection airflow passage 24B, together with the suction chamber 22D, is configured as a passage for the dust collection airflow W2 generated by the fan 48, which will be described later.

The front end of the dust collection air passage section 24B is configured as a fan accommodation section 24C that accommodates the fan 48 described below. When viewed from the left side, the outer shape of the fan accommodation section 24C is formed in a substantially circular shape corresponding to the motor housing section 22H, and protrudes upward compared to the portion of the dust collection air passage section 24B other than the fan accommodation section 24C. A first support tube section 24D (broadly speaking, an element that can be understood as a first support section) is formed in the approximate center of the bottom wall 24K of the fan accommodation section 24C, and the first support tube section 24D is formed in a cylindrical shape with its axial direction in the left-right direction and protrudes to the right from the side housing 24.

A discharge cylinder part 24E (in a broad sense, an element understood as a discharge part) for discharging dust is provided at the rear of the upper end of the fan housing part 24C. The discharge cylinder part 24E is formed in a substantially cylindrical shape with the front-rear direction as the axial direction, and the rear end of the discharge cylinder part 24E is connected to the rear upper end of the fan housing part 24C, so that the discharge cylinder part 24E and the fan housing are connected to each other. The portion 24C is in communication with the portion 24C. The rear end of the discharge tube section 24E is configured so that a dust collection attachment such as a dust box or a connection hose for a dust collector can be attached, so that the dust discharged from the discharge tube section 24E can be collected in a dust box or the like. (FIG. 2 shows an example in which the dust box 100 is attached to the discharge tube portion 24E). In addition to the above, the dust collection attachment also includes a flexible dust collection bag. Various dust collection attachments can be selectively attached to the discharge tube portion 24E. An engaged portion 24J on which a bent portion 120B (to be described later) is caught is provided at the rear end of the discharge cylinder portion 24E.

At the rear end portion of the side housing 24, a second support tube portion 24F (broadly speaking, an element that can be understood as a second support portion) is formed below the first guide wall 24A. The second support tube portion 24F is formed in a cylindrical shape with its axial direction in the left-right direction and protrudes to the right from the bottom wall of the side housing 24. The side housing 24 is provided with a rear tube portion 24G at a diagonal lower rear side of the second support tube portion 24F. The rear tube portion 24G is formed in a cylindrical shape with its axial direction in the left-right direction and protrudes to the right from the bottom wall of the side housing 24. The rear tube portion 24G is arranged so as to overlap the second support tube portion 24F, and a part of the second support tube portion 24F is positioned so as to overlap the radially inner side of the rear tube portion 24G.

As shown in FIG. 8, an inner housing 26 for supporting a drive pulley 66, which will be described later, is provided on the right side of the rear end of the side housing 24. The inner housing 26 is formed into a substantially stepped cylindrical shape that is open to the left side, and is fixed to the side housing 24 so as to cover the rear cylinder part 24G and the second support cylinder part 24F from the right side. The inner housing 26 is integrally formed with a shaft support portion 26A that protrudes to the right. The shaft support portion 26A is formed in a substantially cylindrical shape with the left-right direction as the axial direction, and is disposed coaxially with the rear cylinder portion 24G.

As shown in FIG. 5, the side housing 24 is formed with a surrounding wall 24H surrounding a transmission belt 64, which will be described later. The surrounding wall 24H extends along an overhead line L connecting the axis of the first support tube 24D (motor pulley 54 described later) and the axis of the second support tube 24F (transmission pulley 56 described later) when viewed from the left side. It is formed in a frame shape and protrudes from the side housing 24 to the left side. That is, the surrounding wall 24H extends along a direction that is inclined upward toward the front side when viewed from the left side. The width dimension of the surrounding wall 24H is set to become smaller toward the front side.

(Power transmission mechanism 40)
As shown in FIG. 8, the power transmission mechanism 40 includes a motor 42, a motor pulley 54 as a first pulley, and a transmission pulley 56 as a second pulley. The motor 42 is configured as a brushless motor and is housed in the motor housing portion 22H of the main body housing 22. The motor 42 is electrically connected to the controller 30 and is driven under the control of the controller 30. The motor 42 has a drive shaft 42A whose axial direction is the left-right direction. The right end of the drive shaft 42A is rotatably supported by a motor bearing 44 held in the motor housing portion 22H, and the left end portion of the drive shaft 42A is rotatably supported by a motor bearing 46 held in the first support tube portion 24D of the side housing 24. The left end of the drive shaft 42A protrudes leftward from the side housing 24 and is disposed within the front end of the surrounding wall 24H.

A fan 48 is provided on the left end of the drive shaft 42A so as to rotate integrally with it, and is disposed within the motor housing section 22H of the main housing 22 and the fan accommodating section 24C of the side housing 24. The fan 48 has a fan base 48A, which is formed in a generally circular plate shape with its thickness direction extending in the left-right direction. The right part of the fan 48 (the part to the right of the fan base 48A) is configured as a cooling fan section 48B, and the left part of the fan 48 is configured as a dust collection fan section 48C.

The cooling fan section 48B is configured as a centrifugal fan and is disposed in the motor housing section 22H. Specifically, the cooling fan section 48B has a plurality of blades protruding to the right side from the fan base 48A, and is configured to allow the air flowing in from the center side of the cooling fan section 48B to flow outward in the radial direction. This generates cooling air W1 that flows into the main housing 22 from the intake port 22G, and the cooling air W1 passes through the controller 30 and the motor 42 and flows into the cooling fan section 48B. A ring-shaped first fan guide 50 is provided on the radial outside of the cooling fan section 48B, and the cooling air W1 that flows outward in the radial direction of the cooling fan section 48B is exhausted to the outside of the main housing 22 from an exhaust port 50A formed in the front part of the first fan guide 50.

6 and 8, the dust collection fan section 48C is configured as a centrifugal fan, similar to the cooling fan section 48B, and is arranged in the fan housing section 24C. The dust collection fan section 48C has a plurality of blades protruding to the left side from the fan base 48A, and the air flowing in from the center side of the dust collection fan section 48C flows outward in the radial direction. In addition, a second fan guide 52, which is a substantially bottomed cylindrical shape that opens to the right side, is provided on the radial outside of the dust collection fan section 48C. A communication hole 52A is formed through the center of the bottom wall of the second fan guide 52, and the right end of the first support tube section 24D is inserted into the communication hole 52A. In addition, an opening 52B is formed through the second fan guide 52, and the air flowing out from the dust collection fan section 48C flows from the opening 52B to the exhaust tube section 24E. As a result, the dust collection fan section 48C generates a dust collection wind W2 as an air flow that flows into the suction chamber 22D from the suction port section 22D1 of the main housing 22, and the dust collection wind W2 passes through the dust collection air passage section 24B of the side housing 24 and the communication hole 52A of the second fan guide 52, and flows into the dust collection fan section 48C. The dust collection wind W2 that flows into the dust collection fan section 48C flows radially outward from the dust collection fan section 48C, flows into the exhaust tube section 24E, and is exhausted to the outside of the housing 20 from the rear end of the exhaust tube section 24E.

As shown in Figures 5 and 8, the motor pulley 54 is formed in a generally cylindrical shape with its axial direction extending in the left-right direction, is fixed to the left end of the drive shaft 42A of the motor 42 so as to be rotatable together with the motor pulley 54, and is disposed within the front end of the surrounding wall 24H. The motor pulley 54 is configured as a so-called V-belt pulley, and multiple grooves are formed on the outer periphery of the left side of the motor pulley 54.

The transmission pulley 56 is rotatably connected to the rear end of the side housing 24 via a transmission shaft 58. The transmission shaft 58 is formed in a substantially cylindrical shape with an axial direction extending in the left-right direction. The right end portion of the transmission shaft 58 is rotatably supported by a shaft bearing 60 held by the inner housing 26, and the axially intermediate portion of the transmission shaft 58 is rotatably supported by a shaft bearing 62 held by the second support cylinder portion 24F. The left end of the transmission shaft 58 projects leftward from the side housing 24 and is disposed within the rear end of the surrounding wall 24H. The transmission pulley 56 is formed in a substantially cylindrical shape with the axial direction in the left-right direction, and is fixed to the left end portion of the transmission shaft 58 so as to be integrally rotatable. Like the motor pulley 54, the transmission pulley 56 is configured as a so-called V-belt pulley, and a plurality of grooves are formed on the outer circumference of the transmission pulley 56. The outer diameter of the transmission pulley 56 is set larger than the outer diameter of the motor pulley 54.

An endless transmission belt 64 is stretched (tensioned) around the outer periphery of the motor pulley 54 and the transmission pulley 56, and the transmission belt 64 is configured as a V-belt. As a result, when the motor 42 is driven, the driving force of the motor 42 is transmitted to the transmission shaft 58 by the motor pulley 54, the transmission belt 64, and the transmission pulley 56, causing the transmission shaft 58 to rotate. A pinion gear 58A is formed on the outer periphery of the right end portion of the transmission shaft 58.

(About the drive pulley 66 and driven pulley 72)
As shown in FIGS. 3, 4, and 8, the drive pulley 66 is rotatably connected to the inner housing 26 via a drive shaft 68. The drive shaft 68 is formed into a substantially cylindrical shape with its axis extending in the left-right direction, is inserted into the shaft support portion 26A of the inner housing 26, and is rotatably supported by the shaft support portion 26A. The left end portion of the drive shaft 68 projects leftward from the shaft support portion 26A and is located on the rear side of the transmission shaft 58. A cylindrical transmission gear 70 is provided at the left end of the drive shaft 68 so as to be rotatable therewith, and the transmission gear 70 is meshed with the pinion gear 58A of the transmission shaft 58. The right portion of the drive shaft 68 protrudes to the right from the shaft support portion 26A and is disposed within the rear end portion of the processed recess 22A in the main body housing 22.

The drive pulley 66 is formed in a generally bottomed cylindrical shape that is open to the left. A cylindrical connecting shaft portion 66A with its axial direction in the left-right direction is formed in the center of the bottom wall (right wall) of the drive pulley 66, and the connecting shaft portion 66A protrudes to the left from the bottom wall of the drive pulley 66. The right portion of the drive shaft 68 is fitted into the connecting shaft portion 66A, and the drive pulley 66 is connected to the drive shaft 68 so as to be rotatable together with it. As a result, when the motor 42 is driven, the driving force of the motor 42 is transmitted to the drive shaft 68, and the drive pulley 66 rotates together with the drive shaft 68; specifically, the drive pulley 66 rotates clockwise when viewed from the right side.

The driven pulley 72 is formed in a cylindrical shape with its axis extending in the left-right direction. The driven pulley 72 is disposed within the front end of the machined recess 22A and is rotatably supported by a support shaft 74. The support shaft 74 is fixed to a support plate 76A of a pulley support mechanism 76 for supporting the driven pulley 72, and the pulley support mechanism 76 is fixed to the belt support portion 22B of the main housing 22.

An endless abrasive belt 78 is suspended (suspended) around the drive pulley 66 and the driven pulley 72, and the middle part of the lower end of the abrasive belt 78 in the front-rear direction is adjacent to the lower side of the belt support part 22B. It is located. Note that the lower ends of the drive pulley 66 and the driven pulley 72 are located slightly above the lower surface of the belt support portion 22B. As a result, the drive pulley 66 is rotated by the power transmission mechanism 40, so that the polishing belt 78 rotates along its own circumferential direction, and the driven pulley 72 rotates around the support shaft 74. Therefore, by pressing the intermediate portion of the lower end of the polishing belt 78 in the front-back direction against the workpiece from above, the workpiece can be polished. The drive pulley 66, driven pulley 72, and polishing belt 78 correspond to the processing section of the present invention.

(Regarding the belt cover 80)
1, 2, and 8 to 10, the belt cover 80 is formed in a box shape with a relatively shallow bottom and open to the right side, similar to the side housing 24. The outer shape of the belt cover 80 as viewed from the left side is formed to correspond to the outer shape of the surrounding wall 24H of the side housing 24, and the belt cover 80 extends in a direction that inclines upward toward the front as viewed from the left side. The belt cover 80 is disposed adjacent to the left side of the surrounding wall 24H and is fastened and fixed to the side housing 24. As a result, the surrounding wall 24H is closed by the belt cover 80, and the belt cover 80 covers the motor pulley 54, the transmission pulley 56, and the transmission belt 64 from the left side.

(Regarding the reinforcing portion 90)
As shown in FIG. 5 and FIG. 7 to FIG. 10, the reinforcing portion 90 is provided on the bottom wall 24K of the side housing 24. When viewed from the left side, the reinforcing portion 90 is disposed inside the transmission belt 64 and is located between the motor pulley 54 and the transmission pulley 56. The reinforcing portion 90 extends along the overhead line L, and is formed in a substantially U-shape (concave shape) that opens to the right side when viewed in its longitudinal direction (extension direction of the overhead line L), and protrudes to the left side from the side housing 24. That is, the reinforcing portion 90 is formed in a shape in which a part of the plate-shaped side housing 24 bulges to the left. The width dimension of the reinforcing portion 90 is set to increase toward the rear side. Specifically, the upper and lower side walls 90A extending in the longitudinal direction of the reinforcing portion 90 are disposed so as to be parallel to the transmission belt 64. The reinforcing portion 90 protrudes from the bottom wall 24K to an extent that it partially overlaps with the transmission belt 64 when viewed in the vertical direction. Furthermore, when viewed in the front-rear direction (or the extending direction of the overhead line L), the reinforcing portion 90 protrudes so as to at least partially overlap the motor pulley 54 and the transmission pulley 56. That is, when viewed in a direction perpendicular to the axial direction of the motor pulley 54 (or the transmission pulley 56) (front-rear or up-down direction), at least a portion of the reinforcing portion 90 is configured to overlap the transmission belt 64, the motor pulley 54, or the transmission pulley 56.

Moreover, the upper part of the reinforcing part 90 overlaps with the dust collecting air passage part 24B of the side housing 24 when viewed from the left and right direction. That is, the first guide wall 24A intersects the longitudinal middle part of the reinforcing part 90, and the reinforcing part 90 is configured to increase the volume of the dust collecting air passage part 24B. An inclined part 90B as a second guide part is formed at the front end of the reinforcing part 90, and the inclined part 90B is arranged on the right side (in the direction away from the motor pulley 54) as the reinforcing part 90 goes to the outside (front) in the longitudinal direction. (decreased amount of protrusion). The inclined part 90B is located in the fan housing part 24C, and the front end of the inclined part 90B is connected to the left end of the first support cylinder part 24D. Thereby, the dust-collecting wind W2 flowing forward inside the reinforcing part 90 is guided to the right by the inclined part 90B and guided to the fan accommodating part 24C side (fan 48 side). Incidentally, the inclined portion 90B constitutes a guide mechanism portion 92 that guides the dust collection wind W2 together with the first guide wall 24A described above. Further, the rear end portion of the reinforcing portion 90 is connected to the left end portion of the second support cylinder portion 24F. Further, an inclined portion 90C is formed at the rear end of the reinforcing portion 90, and the inclined portion 90C is inclined to the right (in the direction away from the transmission pulley 56) as the reinforcing portion 90 moves outward (backward) in the longitudinal direction. are doing.

Further, the belt cover 80 described above is provided with a pair of upper and lower first cover ribs 80A at positions corresponding to the reinforcing parts 90, and the first cover ribs 80A are located at positions overlapping with the reinforcing parts 90 when viewed from the left and right direction. (See Figure 5). The first cover rib 80A extends along the longitudinal direction of the reinforcing portion 90 and protrudes from the belt cover 80 to the right side. Specifically, the pair of first cover ribs 80A are inclined in a direction that separates them from each other toward the rear side. A plurality (in this embodiment, three locations) of second cover ribs 80B (see FIG. 5) are formed between the first cover ribs 80A. The second cover rib 80B extends along a direction perpendicular to the longitudinal direction of the reinforcing portion 90, and is connected to the first cover rib 80A by the second cover rib 80B. The first cover rib 80A and the second cover rib 80B are arranged adjacent to the left side of the reinforcing portion 90.

(Conductive tape 110 and conductive plate 120)
As shown in FIG. 12, a conductive tape 110 is provided on the outer periphery of the second fan guide 52. The conductive tape 110 is conductive. The conductive tape 110 is an aluminum tape. An adhesive is applied to one side of the conductive tape 110. The adhesive-applied side of the conductive tape 110 is attached to the outer periphery of the second fan guide 52, thereby fixing the conductive tape 110 to the second fan guide 52. The conductive tape 110 is provided on the entire outer periphery of the second fan guide 52 except for the range of the opening 52B. An extension portion 110a is provided on one end of the conductive tape 110. The extension portion 110a is a part of the conductive tape 110 and extends inward from the outer periphery of the second fan guide 52. The extension portion 110a is a portion that extends in a direction intersecting with the circumferential direction of the second fan guide 52. Although not shown in the figure, the extension portion 110a has a large area and a small area.

As shown in FIG. 12, the belt sander 10 has a conductive plate 120. Most of the conductive plate 120 is located inside the side housing 24. The conductive plate 120 is a metal plate processed by pressing or the like. The conductive plate 120 is bent at the center position in the front-rear direction. The conductive plate 120 has a vertical wall portion 120a at the front. The vertical wall portion 120a is a portion on a flat plate that extends up and down in the front and back. A front end portion of the vertical wall portion 120a is in contact with the extension portion 110a. The left side of the vertical wall portion 120a is in contact with the side housing 24, and the right side is in contact with the second fan guide 52. That is, the vertical wall portion 120a is held between the side housing 24 and the second fan guide 52 in the left-right direction. The conductive plate 120 has a bent portion 120b at the rear. The bent portion 120b is a portion obtained by bending the rear end of the conductive plate 120 upward, and has a mountain-like shape on the upper side. The bent portion 120b engages with the engaged portion 24J. That is, the conductive plate 120 is held by the belt sander 10 by having its front end portion held between the side housing 24 and the second fan guide 52, and its rear end portion engaging with the engaged portion 24J. The bent portion 120b is interposed between the discharge tube portion 24E and the dust collection attachment in the vertical direction (radial direction of the discharge tube portion 24E), and is configured to connect them. Since the upper end of the bent part 120b is shaped like a mountain, it can be elastically deformed by the connected dust collection attachment, thereby making it possible to maintain a suitable connection between the discharge cylinder part 24E and the dust collection attachment. ing.

(effect)
During polishing using the belt sander 10 configured as described above, the operator pulls and operates the trigger 34 of the belt sander 10 to drive the motor 42, and the power transmission mechanism 40 transfers the driving force of the motor 42 to the drive pulley. 66, and the polishing belt 78 rotates in the circumferential direction. Thereby, by pressing the lower surface of the polishing belt 78 against the workpiece, the workpiece is polished.

Further, when the motor 42 is driven, the fan 48 rotates together with the drive shaft 42A of the motor 42. As a result, the cooling fan section 48B of the fan 48 generates the cooling air W1, and the dust collecting fan section 48C of the fan 48 generates the dust collecting air W2.

Specifically, cooling air W1 is generated that flows into the controller housing portion 22C from the intake port 22G of the housing 20. The cooling air W1 flowing into the controller housing part 22C flows to the left inside the motor housing part 22H and is drawn into the cooling fan part 48B. Thereby, the controller 30 and the motor 42 are cooled by the cooling air W1.

On the other hand, as the dust collection fan section 48C rotates, the dust collection air W2 flows toward the dust collection fan section 48C in the dust collection air passage section 24B and the suction chamber 22D of the housing 20. Specifically, the air in the machining recess 22A in the main housing 22 flows from the suction port section 22D1 into the suction chamber 22D, generating the dust collection air W2 that flows from the machining recess 22A into the suction chamber 22D. In addition, dust generated during polishing is rolled up at the rear end of the polishing belt 78. Therefore, the dust collection air W2 containing the dust flows into the suction chamber 22D from the suction port section 22D1. The dust collection air W2 that flows into the suction chamber 22D passes through the dust collection air passage section 24B of the side housing 24, passes through the communication hole 52A of the second fan guide 52, and flows into the dust collection fan section 48C. The dust-collecting air W2 that flows into the dust-collecting fan section 48C flows radially outward from the dust-collecting fan section 48C, passes through the inside of the exhaust tube section 24E, and is exhausted rearward from the rear end of the exhaust tube section 24E. Therefore, dust generated during the polishing process is discharged from the exhaust tube section 24E and collected in the dust box 100, etc.

By the way, in the belt sander 10, a motor pulley 54 and a transmission pulley 56 are supported by a side housing 24 made of resin, and a transmission belt 64 is wound around the motor pulley 54 and the transmission pulley 56. That is, a compressive force along the overhead line L acts on the side housing 24 due to the tension of the transmission belt 64 that is stretched around the motor pulley 54 and the transmission pulley 56 . Therefore, if the side housing 24 were to deform due to the compressive force, the supporting performance for the motor pulley 54 and the transmission pulley 56 would be reduced, which could affect the operation of the belt sander 10. In this case, there is a possibility that the workability of the belt sander 10 may be reduced.

Here, the side housing 24 is provided with a reinforcing portion 90, and the reinforcing portion 90 protrudes from the side housing 24 toward one side (left side) in the axial direction of the motor pulley 54 and the transmission pulley 56. Specifically, the reinforcing portion 90 extends along an overhead line L that passes through the axis of the motor pulley 54 and the axis of the transmission pulley 56, projects to the left from the side housing 24, and extends from the longitudinal direction of the side housing 24. It is formed in a concave shape (U-shape) that opens to the right when viewed. Therefore, the portion of the side housing 24 between the first support tube portion 24D and the second support tube portion 24F can be reinforced by the reinforcement portion 90. Further, the reinforcing portion 90 protrudes from the bottom wall 24K to such an extent that it partially overlaps the transmission belt 64 when viewed in the vertical direction. Further, when viewed in the front-rear direction (or the extending direction of the overhead wire L), the reinforcing portion 90 protrudes so as to at least partially overlap the motor pulley 54 and the transmission pulley 56. That is, when viewed in the direction (front-back or up-down direction) orthogonal to the axial direction of the motor pulley 54 (or the transmission pulley 56), at least a portion of the reinforcing portion 90 is connected to the transmission belt 64, the motor pulley 54, or the transmission pulley 56. are configured to overlap. By doing so, it is possible to effectively utilize the belt tension space, which was conventionally a dead space, and to improve the strength of the side housing 24. Therefore, the bending rigidity of the side housing 24 in the left-right direction can be increased compared to the case where the reinforcing portion 90 is omitted in the side housing 24. As a result, the belt sander 10 can be operated satisfactorily while maintaining good support for the motor pulley 54 and the transmission pulley 56 by the side housing 24. As described above, the workability of the belt sander 10 can be improved. Note that in order to improve dust collection efficiency, which will be described later, in this embodiment, the reinforcing portion 90 is shaped to protrude on one side (left side) and be concave on the other side (right side), but this is merely for the purpose of improving strength. If so, there is no need to provide a recess, and the strength of the side housing 24 may be improved simply by ribs extending in the direction in which the belt is stretched.

Further, the side housing 24 is made of resin. Thereby, it is possible to reduce the weight of the belt sander 10 and to improve the weight balance in the left and right direction. That is, for example, by making the side housing 24 made of metal, the bending rigidity of the side housing 24 can be increased, and the supporting performance for the motor pulley 54 and the transmission pulley 56 can be improved. However, if the side housing 24 is made of metal, the weight of the side housing 24 and the belt sander 10 will increase. Further, since the side housing 24 constitutes the left end portion of the housing 20, the weight balance of the belt sander 10 in the left-right direction may deteriorate. Specifically, the side housing 24 is located on the left side with respect to the polishing belt 78. As a result, in the belt sander 10 that performs polishing by pressing the polishing belt 78 against the workpiece from above, the amount of polishing by the left side of the polishing belt 78 is greater than the amount of polishing by the right side of the polishing belt 78. Therefore, in order to make the amount of polishing uniform in the left-right direction, the operator needs to work while correcting the posture of the belt sander 10, which may deteriorate the workability of the belt sander 10. On the other hand, in this embodiment, the side housing 24 is made of resin, so that the weight of the side housing 24 and the belt sander 10 can be reduced. Further, by making the side housing 24 made of resin, it is possible to improve the weight balance of the belt sander 10 in the left-right direction and to equalize the amount of polishing of the workpiece by the polishing belt 78 in the left-right direction. Therefore, the workability of the belt sander 10 can be further improved.

The upper part of the side housing 24 is configured as a dust collection air duct 24B through which the dust collection air W2 generated by the fan 48 (dust collection fan section 48C) passes. Furthermore, the reinforcing section 90 is arranged at a position overlapping the dust collection air duct 24B and protrudes from the side housing 24 to the left (opposite the dust collection air duct 24B) to expand the dust collection air duct 24B. This makes it possible to reduce the flow resistance of the dust collection air W2 flowing through the dust collection air duct 24B. As a result, the dust collection air W2 can be smoothly flowed toward the fan 48 and discharged from the exhaust tube section 24E. Therefore, the dust collection efficiency by the fan 48 can be increased. In FIG. 10, the movement of the dust collection air W2 is simplified, but as described above, the dust collection air W2 is configured to be able to pass through the space expanded by the reinforcing section 90 (recess). Therefore, the dust collection air W2 from the suction chamber 22D is configured to move leftward, pass through the reinforcing portion 90 (recess), move rightward from there to the inside of the second fan guide 52, and move leftward from there to the exhaust tube portion 24E.

Moreover, the reinforcing part 90 is formed in a concave shape (U-shape) that is open toward the dust collecting air path part 24B side when viewed from the longitudinal direction of the reinforcing part 90. Therefore, the upper and lower side walls 90A extending in the longitudinal direction of the reinforcing part 90 function as guide walls that guide the dust-collecting wind W2 in the reinforcing part 90 toward the fan 48 side. Therefore, the dust-collecting wind W2 in the reinforcing portion 90 can be smoothly flowed toward the fan 48 side.

The reinforcing portion 90 is disposed inside the transmission belt 64 when viewed from the left side. Therefore, the reinforcing portion 90 can be provided in the side housing 24 by effectively utilizing the inner space of the transmission belt 64.

Further, the width of the reinforcing portion 90 is set to increase toward the rear side. That is, the outer surfaces (upper surface and lower surface) of the side wall 90A of the reinforcing portion 90 are arranged parallel to the transmission belt 64. Thereby, compared to the case where the width dimension of the reinforcing part 90 is set constant to the width dimension of the front end part, the outer shape of the reinforcing part 90 seen from the left and right direction can be made larger. Thereby, the bending rigidity of the side housing 24 can be effectively increased, and the volume of the dust collection air passage section 24B can be effectively increased. In order to make the outer shape of the reinforcing portion 90 as large as possible, the outer surface (upper surface and lower surface) of the side wall 90A was made parallel to the transmission belt 64, but The width may be configured to increase gradually or stepwise. By doing so, it becomes easy to effectively utilize the tension space of the transmission belt 64 and increase the size of the reinforcing portion 90.

Furthermore, inside the side housing 24, a first guide wall 24A is formed. The first guide wall 24A extends in the front-rear direction with the up-down direction as the plate thickness direction. Thereby, the dust collecting air W2 flowing into the dust collecting air passage section 24B can be guided to the front side by the first guide wall 24A and can be smoothly flowed toward the fan 48 side. Moreover, the side housing 24 can be reinforced by the first guide wall 24A. Thereby, the bending rigidity of the side housing 24 can be further increased.

Further, the vertical position of the first guide wall 24A substantially coincides with the lower wall of the suction chamber 22D in the main body housing 22, and the first guide wall 24A constitutes the lower wall of the dust collection air passage section 24B. Therefore, it is possible to suppress the dust flowing into the side housing 24 due to the dust collection wind W2 from staying in the lower part of the side housing 24.

Further, the first guide wall 24A intersects with the longitudinally intermediate portion of the reinforcing portion 90. Thereby, the reinforcing portion 90 can also be reinforced by the first guide wall 24A. Therefore, the bending rigidity of the side housing 24 can be effectively increased.

In addition, a sloping portion 90B is provided at the front end of the bottom wall of the reinforcing portion 90, and the sloping portion 90B is sloping to the right as it moves outward in the longitudinal direction of the reinforcing portion 90. This allows the dust-collecting wind W2 that flows into the reinforcing portion 90 to be guided toward the fan housing portion 24C by the sloping portion 90B. This allows the dust-collecting wind W2 to flow more efficiently toward the fan housing portion 24C.

The inclined portion 90B is provided in the fan housing portion 24C, and the front end of the inclined portion 90B is connected to the left end of the first support cylinder portion 24D. This allows the dust collection wind W2 to flow effectively toward the fan 48.

Further, an inclined portion (inclined portions 90B, 90C) is provided at the end of the reinforcing portion 90. With this configuration, the reinforcing part (convex part) 90 can be arranged close to the two pulleys while suppressing interference between the reinforcing part 90 and the motor pulley 54 or the transmission pulley 56. The length can further improve durability.

In addition, the belt cover 80 covering the motor pulley 54, the transmission pulley 56, and the transmission belt 64 is provided with a first cover rib 80A and a second cover rib 80B, and the first cover rib 80A and the second cover rib 80B are arranged adjacent to the left side of the reinforcement part 90. For this reason, for example, when the belt cover 80 is bent to the right side (side housing 24 side), the first cover rib 80A and the second cover rib 80B abut against the reinforcement part 90, and the reinforcement part 90 can support the belt cover 80 from the left side. That is, the protruding reinforcement part 90 directly or indirectly contacts the belt cover 80, thereby suppressing deformation of the belt cover 80. Therefore, for example, even if an impact is applied to the belt cover 80 when it is dropped, the reinforcement part 90 can suppress deformation of the belt cover 80 and suppress damage to the belt cover 80. In addition, the durability of the belt cover 80 can be improved. Therefore, the reinforcing portion 90, which increases the bending rigidity of the side housing 24 and improves the dust collection efficiency, can increase the overall rigidity of the belt sander 10.

In addition, the conductive tape 110 and the conductive plate 120 allow static electricity to escape to the dust collection attachment. As described above, in this embodiment, the dust collection efficiency can be improved, but when the dust collection efficiency is increased, the dust flows at a high speed, and static electricity is easily generated due to friction between the resin part and the dust. If static electricity accumulates, it may have a negative effect on the internal electronic components. Therefore, in this embodiment, the conductive tape 110 is provided on the outer periphery of the second fan guide 52, which is particularly prone to static electricity, so that the static electricity (charge) accumulated in the second fan guide 52 can be moved through the conductive tape 110. Furthermore, the conductive plate 120 (vertical wall portion 120a) is connected to the extension portion 110a provided at the end of the conductive tape 110, and the static electricity accumulated in the second fan guide 52 can be moved to the conductive plate 120. A bent portion 120b is provided at the rear end of the conductive plate 120, and a dust collection attachment is connected to the bent portion 120b. Therefore, the static electricity accumulated in the second fan guide can be released to the dust collection attachment. In addition, in this embodiment, in order to move the static electricity, a flexible tape-like conductive tape 110 is combined with a conductive plate 120, which is a metal plate having a hard property. In other words, a static electricity conductive configuration is constructed by combining things with different flexibility. In this way, a highly flexible conductive material is placed on a circular shape such as a fan guide, and a less flexible material is used for linear conduction, so that the static electricity can be moved suitably. In addition, since the conductive plate 120 is connected to the dust collection attachment, it is advantageous to have a harder material. In particular, in this embodiment, the elasticity of the conductive plate 120 is used to connect to the dust collection attachment and to move the static electricity, so a harder material such as a metal plate is more suitable than a tape.

In this embodiment, the amount of protrusion of the reinforcing portion 90 from the side housing 24 to the left can be set as desired. For example, as shown in FIG. 11, the first cover rib 80A and the second cover rib 80B may be omitted in the belt cover 80, and the amount of protrusion of the reinforcing portion 90 may be set so that the reinforcing portion 90 is disposed adjacent to the right side of the belt cover 80. This makes it possible to more effectively increase the bending rigidity of the side housing 24 and more effectively increase the volume of the dust collection air passage portion 24B in the side housing 24. In this case, since the reinforcing portion 90 is disposed adjacent to the right side of the belt cover 80, the overall rigidity of the belt sander 10 can also be increased, as described above.

10 Belt sander (work machine)
22 Main body housing (housing part)
22D Suction chamber 24 Side housing (support member)
24A First guide wall (first guide part)
24B Dust collection air passage section (passage section)
24C Fan accommodating part 24D First support cylinder part (first support part)
24F Second support cylinder part (second support part)
40 Power transmission mechanism 42 Motor 48 Fan 54 Motor pulley (first pulley)
56 Transmission pulley (second pulley)
64 Transmission belt (belt)
66 Drive pulley (processing part)
72 Driven pulley (processing section)
78 Polishing belt (processing section)
80 Belt cover (cover member)
90 Reinforcement part 90B Inclined part (second guide part)
92 Guide mechanism L Overhead wire W2 Dust collection wind (air flow)

Claims (15)

a power transmission mechanism including a first pulley, a second pulley, and a belt stretched across the first pulley and the second pulley;
a support member that supports the first pulley and the second pulley;
Provided on the support member, protrudes in the axial direction of the first pulley, and extends along an imaginary line connecting the axis of the first pulley and the axis of the second pulley when viewed from the axial direction. Reinforcement part;
A work machine equipped with The power transmission mechanism includes a motor and a fan that rotates due to drive of the motor and generates an air flow,
The working machine according to claim 1, wherein the support member has a passage portion through which the air flow passes, and the passage portion is expanded by the reinforcing portion. a processing unit that is operated by the driving force transmitted from the power transmission mechanism to process a workpiece,
3. The work machine according to claim 2, wherein the air flow is a dust collecting wind for collecting dust generated during machining. the first pulley, the second pulley, and the belt are located on one side in the axial direction with respect to the support member,
The reinforcing portion protrudes from the support member toward one side in the axial direction,
3. The work machine according to claim 2, wherein the reinforcing portion is located between the first pulley and the second pulley and on the inside of the belt when viewed in the axial direction. the first pulley and the fan are provided on a drive shaft of the motor so as to be rotatable together with each other,
The fan is located inside the passage,
5. The work machine according to claim 4, wherein the reinforcing portion is formed in a concave shape that is open toward the passage portion when viewed in the longitudinal direction. The outer diameter of the second pulley is set larger than the outer diameter of the first pulley,
The working machine according to claim 1, wherein the reinforcing portion gradually or stepwise expands toward the second pulley in a direction perpendicular to both the axial direction and the extending direction of the overhead wire. The work machine according to claim 2, wherein the support member is provided with a guide mechanism that guides the flow of the airflow. The motor is housed in a housing part with the left-right direction as an axial direction, and the housing part has a suction chamber that sucks air outside the housing part by the air flow,
The support member is assembled to the housing part from one side in the left-right direction, and the passage part communicates with the suction chamber,
A fan accommodating portion for accommodating the fan is provided at one end in the front-rear direction of the passage portion,
The working machine according to claim 7, wherein the guide mechanism section includes a first guide section that extends in the front-rear direction and guides the airflow toward the fan. The work machine according to claim 8, wherein the front first guide portion constitutes the lower wall of the passage portion. The work machine according to claim 9, wherein the first guide portion intersects with a longitudinally intermediate portion of the reinforcing portion when viewed from the left and right. The first pulley and the second pulley are configured to be rotatable about the left-right direction,
The reinforcing portion protrudes from the supporting member to one side in the left-right direction,
The working machine according to claim 8, wherein the guide mechanism section has a second guide section provided on the reinforcing section, and the second guide section guides the airflow to the other side in the left-right direction. The work machine according to claim 11, wherein the second guide portion is located in the fan housing portion. The processing section is
a drive pulley that rotates by the driving force transmitted from the power transmission mechanism;
a driven pulley arranged in parallel with the drive pulley;
a grinding belt that is stretched around the drive pulley and the driven pulley and rotates in a circumferential direction as the drive pulley rotates;
The work machine according to claim 3, further comprising: A cover member that covers the first pulley, the second pulley, and the belt is attached to the support member,
The work machine according to claim 1 , wherein a portion of the cover member is disposed adjacent to the reinforcing portion in a protruding direction of the reinforcing portion. The work according to claim 1, wherein at least a portion of the reinforcing portion is configured to overlap the first pulley, the second pulley, or the belt when viewed in a direction perpendicular to the axial direction. Machine.

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