JP7555787B2 - Power tools - Google Patents

Description

The present disclosure relates to an electric power tool configured to oscillate a tool tip.

There is known a power tool (so-called vibration tool) that is configured to perform machining work on a workpiece by driving a tool tip attached to a spindle to swing within a specified angle range. For example, in the vibration tool disclosed in Patent Document 1, the drive mechanism including the spindle is housed in a drive mechanism housing.

JP 2017-144539 A

The assembly process of the drive mechanism to the housing is relatively complicated. Therefore, in this respect, there is room for further improvement in the above-mentioned vibration tool.

The purpose of this disclosure is to provide a technology that contributes to streamlining the assembly work of the drive mechanism in a power tool that oscillates a tool tip.

According to one aspect of the present disclosure, there is provided an electric power tool including a motor, a spindle, a rocking member, a housing, a first cover portion, and a second cover portion.

The motor has an output shaft. The output shaft is rotatable about a rotation axis extending in a first direction. The spindle is configured to be able to mount a tool. The spindle is rotatable about a drive axis extending parallel to the rotation axis. The oscillating member is operably connected to the output shaft and the spindle. The oscillating member is configured to oscillate about the drive axis in response to rotation of the output shaft, thereby causing the spindle to rotate back and forth about the drive axis.

The housing accommodates the motor, the spindle, and the oscillating member. The housing has a first opening and a second opening. The first opening and the second opening are provided on either side of the oscillating member in the second direction. The second direction is a direction in which a straight line perpendicular to the rotation axis of the output shaft and the drive shaft extends. The first cover portion closes the first opening. The second cover portion closes the second opening.

The housing of the power tool of this embodiment is provided with a first opening and a second opening on both sides of the oscillating member in the second direction. This allows an assembly worker to insert the oscillating member into the housing in the second direction from the first opening or the second opening. This streamlines the assembly work of the oscillating member to the housing. In addition, the first cover part and the second cover part cover the first opening and the second opening, reducing the possibility of foreign matter entering the housing.

In one aspect of the present disclosure, each of the first cover portion and the second cover portion may be formed of an elastic body. According to this aspect, the first cover portion and the second cover portion can more reliably close the first opening and the second opening, respectively.

In one aspect of the present disclosure, the first cover portion and the second cover portion may be connected to each other to form a single cover member. According to this aspect, the first cover portion and the second cover portion are realized that are easy to attach to the housing while reducing the number of parts.

In one aspect of the present disclosure, the entire single cover member may be made of the same material. According to this aspect, the manufacturing cost of the cover member can be reduced.

In one aspect of the present disclosure, the single cover member may be formed in an annular shape and removably attached to the housing around the accommodating portion of the oscillating member. The first cover portion and the second cover portion may be biased in a direction to close the first opening and the second opening, respectively. According to this aspect, a cover member that is easy to attach to the housing and difficult to come off from the housing is realized.

In one aspect of the present disclosure, the first opening may be disposed on the opposite side of the spindle from the output shaft in the second direction. The dimension of the first opening in the first direction may be greater than the dimension of the second opening in the first direction. According to this aspect, the first opening and the second opening can be formed with dimensions suitable for different applications.

In one aspect of the present disclosure, the center of the first opening in the first direction and the center of the second opening in the first direction may be offset in the first direction. According to this aspect, the first opening and the second opening can be formed at positions suitable for different applications.

In one aspect of the present disclosure, at least one of the first cover part and the second cover part has an arc-shaped surface that faces the inside of the housing and bulges outward. According to this aspect, it is possible to reduce the possibility that the first cover part and the second cover part will interfere with the internal mechanism of the housing.

FIG. 2 is a cross-sectional view taken along line II-II in FIG. 1. FIG. FIG. 2 is a partially enlarged view of FIG. 1 (however, the tip tool is not shown). 5 is a cross-sectional view taken along line VV in FIG. 4 (however, the outer housing is not shown). FIG. FIG. 2 is an exploded perspective view of the upper shell and the lever. 13 is an explanatory diagram of the assembly of the lever to the upper shell. FIG. 13 is an explanatory diagram of the assembly of the lever to the upper shell. FIG. FIG. 4 is a right side view of the switch unit and the switch holder when the switch lever is in the off position (however, part of the switch holder is not shown). 11 is a right side view of the switch unit and the switch holder when the switch lever is in the on position. FIG. 3 is a cross-sectional view taken along line XII-XII in FIG. 2. 13 is a cross-sectional view taken along line XIII-XIII in FIG. 12. FIG.

The vibration tool 1 according to the embodiment will be described below with reference to the drawings. The vibration tool 1 is an example of a power tool that performs processing work on a workpiece (not shown) by driving a tip tool 91 to oscillate.

First, the outline of the vibration tool 1 will be described. As shown in FIG. 1 and FIG. 2, the vibration tool 1 includes a long housing (also called a tool body) 10. A drive mechanism 5 including a spindle 51 and a motor 4 are housed in one end of the housing 10 in the longitudinal direction. The spindle 51 is arranged so that the longitudinal axis of the spindle 51 (the drive axis A1 of the tip tool 91) is substantially perpendicular to the longitudinal axis of the housing 10. One end of the spindle 51 in the axial direction protrudes from the housing 10 and is exposed to the outside. This one end constitutes a tool mounting section 511 to which the tip tool 91 can be attached. In addition, a battery mounting section 391 to which a battery 93 can be attached is provided in the other end of the housing 10 in the longitudinal direction. The vibration tool 1 operates using power supplied from the battery 93. The drive mechanism 5 is configured to use the power from the motor 4 to swing the tip tool 91 attached to the tool mounting section 511 within a predetermined angle range around the drive axis A1.

The detailed configuration of the vibration tool 1 will be described below. In the following description, for convenience, the extension direction of the drive shaft A1 is defined as the vertical direction of the vibration tool 1. In the vertical direction, the tool mounting portion 511 side of the spindle 51 is defined as the lower side of the vibration tool 1, and the opposite side is defined as the upper side. A direction perpendicular to the drive shaft A1 and roughly corresponding to the longitudinal direction of the housing 10 is defined as the front-rear direction of the vibration tool 1. In the front-rear direction, the end side of the housing 10 in which the spindle 51 is housed is defined as the front side of the vibration tool 1, and the end side in which the battery 93 is mounted is defined as the rear side. A direction perpendicular to the vertical direction and the front-rear direction is defined as the left-right direction.

First, the configuration of the housing 10 will be described. As shown in Figures 1 and 2, the housing 10 of this embodiment is configured as a so-called vibration-proof housing. Specifically, the housing 10 includes an elongated outer housing 2 that forms the outer shell of the vibration tool 1, and an elongated inner housing 3 housed in the outer housing 2. The outer housing 2 and the inner housing 3 are elastically connected to each other so as to be movable relative to each other.

In the front-to-rear direction, the outer housing 2 includes a front end portion 21, a rear end portion 23, and a central portion 22 that connects the front end portion 21 and the rear end portion 23.

The front end 21 is formed in a generally rectangular box shape. The front end 31 of the inner housing 3 is disposed inside the front end 21. A lever 67 is supported at the upper front end of the front end 21. In this embodiment, the lever 67 is disposed directly above the spindle 51 and is rotatable around the drive shaft A1. The lever 67 is an operating member for clamping the tip tool 91 by the clamp mechanism 6 described below and for releasing the clamping. In addition, an opening 215 is provided at the rear end of the upper wall portion 211 of the front end 21. A sliding operating unit 275 is exposed through this opening 215 so as to be operable from the outside. The operating unit 275 is an operating member for switching the switch unit 26 for starting the motor 4 between an on state and an off state.

The rear end 23 is formed in a cylindrical shape that widens toward the rear (increases in cross-sectional area). The elastic connecting portion 37 and rear end 39 of the inner housing 3 are disposed inside the rear end 23.

The central portion 22 is formed in a cylindrical shape and extends linearly in the front-rear direction. The central portion 22 is the portion that is gripped by the user. Therefore, hereinafter, the central portion 22 is also referred to as the grip portion 22. The grip portion 22 is formed to be thinner than the front end portion 21 and the rear end portion 23 so that it is easy for the user to grip. In other words, the outer periphery of the cross section of the grip portion 22 is shorter than the outer periphery of the cross section of the front end portion 21 and the rear end portion 23.

In this embodiment, the outer housing 2 is formed by connecting an upper shell 201 and a lower shell 205 that are formed separately. More specifically, the outer housing 2 is formed by stacking the upper shell 201 and the lower shell 205 in the vertical direction and connecting them with screws at multiple points. Both the upper shell 201 and the lower shell 205 are made of synthetic resin.

As shown in Figures 1 to 3, in the front-rear direction, the inner housing 3 includes a front end portion 31, an extension portion 35, an elastic connecting portion 37, and a rear end portion 39.

The front end 31 is a portion that houses the drive mechanism 5 and the motor 4. More specifically, as shown in Figures 3 and 4, the front end 31 includes a first housing portion 311, a second housing portion 312, a third housing portion 313, and a cover portion 314.

The first housing section 311 is a portion of the drive mechanism 5 that houses the spindle 51, a part of the oscillating member 536 described later, and the clamp mechanism 6. The first housing section 311 is formed in a cylindrical shape extending in the vertical direction. The second housing section 312 is a portion that houses the motor 4. The second housing section 312 is formed in a cylindrical shape with a larger diameter than the first housing section 311. The second housing section 312 is arranged on the rear side of the first housing section 311. In addition, the second housing section 312 is shorter in the vertical direction than the first housing section 311, and the lower end of the second housing section 312 is above the lower end of the first housing section 311. The third housing section 313 is a portion of the drive mechanism 5 that houses the transmission mechanism 53. The third housing section 313 is arranged on the rear side of the first housing section 311 and below the second housing section 312. The third storage section 313 is in communication with the first storage section 311 and the second storage section 312. The cover section 314 is a section that covers the opening at the upper end of the second storage section 312.

As shown in Figs. 1 to 3, the extension 35 is a portion that extends rearward from the rear end of the front end portion 31. The extension 35 also corresponds to at least a portion of the grip portion 22 of the outer housing 2. "Corresponding to at least a portion of the grip portion 22" can also be rephrased as "at least a portion of the grip portion 22 accommodates a part or the entire extension 35." In this embodiment, the length of the extension 35 in the front-rear direction is approximately the same as the length of the grip portion 22 in the front-rear direction, and approximately the entire extension 35 is disposed within the grip portion 22.

The extension portion 35 includes an outer extension portion 351 that forms the outer contour of the extension portion 35, and an inner extension portion 353 disposed within the outer extension portion 351. The outer extension portion 351 is formed in a rectangular tube shape and extends rearward from the front end portion 31 (more specifically, the rear end portion of the second storage portion 312). The inner extension portion 353 extends rearward within the outer extension portion 351 from the front end portion 31 (more specifically, the rear end portion of the second storage portion 312)) to the rear end of the outer extension portion 351. In this embodiment, the inner extension portion 353 is formed in a rectangular plate shape and extends linearly on a virtual plane P (which can also be said to be a plane including the drive shaft A1 and the rotation shaft A2) that passes through the center of the vibration tool 1 in the left-right direction (see FIG. 12).

The elastic connecting portion 37 extends rearward from the rear end of the extension portion 35 and connects the extension portion 35 and the rear end portion 39 so that the extension portion 35 and the rear end portion 39 can move relative to each other. More specifically, the elastic connecting portion 37 includes a plurality of elastic members 371 that connect the outer extension portion 351 and the rear end portion 39 in the front-rear direction. In this embodiment, four elastic members 371 are arranged around the long axis of the inner housing 3 and spaced apart from each other. Each elastic member 371 is configured to be more easily elastically deformed than other parts of the inner housing 3. More specifically, each elastic member 371 is formed in a band shape that is easily elastically deformed (flexible). In addition, each elastic member 371 is formed of a material with a lower elastic coefficient than other parts of the inner housing 3. The elastic members 371 can effectively suppress the transmission of vibration from the front end portion 31 to the rear end portion 39.

The rear end 39 is formed in a generally rectangular box shape. The rear end 39 is disposed inside the rear end 23 of the outer housing 2.

As shown in Figures 1 to 3, the inner housing 3 is formed by connecting a metal housing 301 and a resin housing 305 that are formed separately from each other.

The metal housing 301 is a single member made of metal. The front portion of the metal housing 301 is configured as a housing for the drive mechanism 5 and the motor 4, and includes the first housing portion 311, the second housing portion 312, and the third housing portion 313 described above. On the other hand, the rear portion of the metal housing 301 is configured by the inner extension portion 353. In other words, the metal housing 301 configures part of the front end portion 31 and part of the extension portion 35.

On the other hand, the resin housing 305 is formed by connecting a right shell 306 and a left shell 307 made of synthetic resin separately in the left-right direction. The resin housing 305 includes the above-mentioned cover portion 314, the outer extension portion 351, the elastic connecting portion 37, and the rear end portion 39. In other words, the resin housing 305 constitutes a part of the front end portion 31, a part of the extension portion 35, the elastic connecting portion 37, and the rear end portion 39.

The inner housing 3 is formed by fixing the metal housing 301 to the right shell 306 and the left shell 307 via screws, with the inner extension 353 of the metal housing 301 sandwiched between the right shell 306 and the left shell 307 (more specifically, the parts that make up the outer extension 351) from the left and right directions.

The elastic connection structure between the outer housing 2 and the inner housing 3 will be described in detail later.

The internal structure of the inner housing 3 is explained below.

First, the internal structure of the front end 31 will be described. As shown in FIG. 4, the front end 31 mainly houses the motor 4, the drive mechanism 5, and the clamp mechanism 6.

The motor 4 is a brushless DC motor and includes a stator, a rotor disposed radially inside the stator, and an output shaft 413 that rotates integrally with the rotor. The motor 4 is accommodated in the second accommodation section 312 so that the rotation axis A2 of the output shaft 413 extends directly behind the drive shaft A1 and parallel to the drive shaft A1 (i.e., in the vertical direction). The output shaft 413 protrudes downward beyond the stator. A fan 45 for cooling the motor 4 is fixed to the output shaft 413.

As shown in FIG. 4, the drive mechanism 5 mainly includes a spindle 51 and a transmission mechanism 53.

The spindle 51 is a long, substantially cylindrical member. In this embodiment, the spindle 51 is accommodated in the lower portion of the first accommodation portion 311. The spindle 51 is supported rotatably around the drive shaft A1 by two bearings (specifically, ball bearings) 513, 514 held in the first accommodation portion 311. As described above, the lower end of the spindle 51 is configured as a tool attachment portion 511 to which the tip tool 91 (see FIG. 1) can be attached.

The transmission mechanism 53 is a well-known mechanism configured to transmit the power of the motor 4 (the rotational power of the output shaft 413) to the spindle 51 and rotate the spindle 51 back and forth within a predetermined angle range around the drive axis A1. The transmission mechanism 53 includes an eccentric shaft 531, a drive bearing 534, and a swinging member 536.

The eccentric shaft 531 is a shaft coaxially connected to the output shaft 413 of the motor 4. The eccentric shaft 531 is rotatably supported by bearings held at the lower end of the second housing portion 312 and the lower end of the third housing portion 313. The eccentric shaft 531 has an eccentric portion that is eccentric with respect to the rotation axis A2. The inner ring of the drive bearing 534 is attached to the eccentric portion.

4 and 5, the oscillating member 536 is a member that operably connects the drive bearing 534 and the spindle 51. The oscillating member 536 extends across the first housing portion 311 and the third housing portion 313. The oscillating member 536 has a first end portion 537 formed in an annular shape and a bifurcated second end portion 538. The first end portion 537 is fixed to the outer periphery of the spindle 51 between the two bearings that support the spindle 51. The second end portion 538 is arranged so as to abut against the outer periphery of the outer ring of the drive bearing 534 from the left and right sides. The oscillating member 536 has a symmetrical shape with respect to a virtual plane that passes through the center in the vertical direction. The thickness of the first end portion 537 in the vertical direction is greater than the thickness of the second end portion 538 in the vertical direction.

When the motor 4 is driven, the eccentric shaft 531 rotates integrally with the output shaft 413, and the oscillating member 536 is oscillated within a predetermined angle range around the drive axis A1 of the spindle 51. The spindle 51 rotates back and forth around the drive axis A1 within a predetermined angle range in accordance with the oscillating motion of the oscillating member 536. As a result, the tip tool 91 fixed to the spindle 51 is driven to oscillate around the drive axis A1, making it possible to carry out machining work.

In this embodiment, the inner housing 3 has a structure for facilitating the assembly of the drive mechanism 5 to the inner housing 3. Specifically, as shown in Figs. 4 and 5, the inner housing 3 (specifically, the front end 31) has a front opening 323 and a rear opening 324 at positions facing the swinging member 536 (specifically, the first end 537 and the second end 538) on the front and rear sides of the swinging member 536, respectively.

The front opening 323 is provided in the front wall of the front end 31 (first housing portion 311). More specifically, the front opening 323 is provided so as to roughly correspond to the area between the upper bearing 513 and the lower bearing 514 in the vertical direction. The front opening 323 is an opening for inserting the oscillating member 536 into the inner housing 3 when the drive mechanism 5 is assembled. Therefore, the vertical height of the front opening 323 is set to be at least greater than the maximum thickness of the oscillating member 536 (the thickness of the first end 537). In addition, the left-right width of the front opening 323 is set to be at least greater than the maximum width of the oscillating member 536 (the distance between the outer side surfaces of the second end 538).

The rear opening 324 is provided in the rear wall of the front end 31 (third housing section 313). The rear opening 324 is an opening into which a tool is inserted to properly position the second end 538 of the oscillating member 536 relative to the drive bearing 534 when the drive mechanism 5 is assembled. The vertical height of the rear opening 324 is set smaller than the vertical height of the front opening 323. The left-right width of the rear opening 324 is set at least larger than the distance between the outer side surfaces of the second end 538.

The vertical center position of the front opening 323 is shifted upward from the vertical center position of the rear opening 324. This is for the following reason. When assembled, the oscillating member 536 needs to be positioned in the vertical direction and in the circumferential direction around the drive shaft A1 at a position (hereinafter referred to as the mounting position) where the second end 538 properly abuts against the outer ring of the drive bearing 534. In addition, in this embodiment, when the oscillating member 536 is in the mounting position, the first end 537 is positioned on the inner ring of the bearing 514 below the spindle 51. Since the first housing portion 311 needs to hold the bearing 514, the front opening 323 cannot be formed in the entire area of the first housing portion 311 just in front of the first end 537. Therefore, in this embodiment, the position of the front opening 323 is shifted upward.

In this embodiment, the spindle 51, transmission mechanism 53, and motor 4 are assembled to the inner housing 3 (specifically, the front end portion 31) using the front opening 323 and rear opening 324 in the following procedure.

First, the worker fits the bearing 514 into a predetermined position in the first housing 311 through the opening at the lower end of the first housing 311 and fixes it with a retaining ring. The worker then inserts the oscillating member 536 into the first housing 311 from the front opening 323, and further moves the oscillating member 536 downward to place it in the mounting position. The first end 537 is placed on the inner ring of the bearing 514. The worker then inserts the spindle 51 into the bearing 514 from below, and presses the lower end of the spindle 51 into the bearing 514 to fix it. The worker inserts a tool from the rear opening 324 to hold the oscillating member 536 in the mounting position. The worker inserts the rotor, with the fan 45, eccentric shaft 531, and drive bearing 534 attached to the output shaft 413, into the front end 31 through the opening at the upper end of the second housing 312. The eccentric shaft 531 is pressed into the two bearings, completing the assembly.

As described above, in this embodiment, the front opening 323 and the rear opening 324 are provided on the front and rear sides of the oscillating member 536. This makes it possible to insert the oscillating member 536 from the front opening 323 toward the rear into the front end 31. In other words, the insertion direction of the oscillating member 536 can be made different from the insertion direction of the spindle 51, the output shaft 413 of the motor 4, and the eccentric shaft 531. When the oscillating member 536 is inserted into the front end 31 from below, as in the case of the spindle 51, it becomes necessary to close and fix the lower end of the front end 31 with another member after assembling the oscillating member 536. In contrast, according to this embodiment, the assembling work of the oscillating member 536 to the front end 31 can be streamlined.

Furthermore, as shown in Figures 3 to 5, in this embodiment, a cover member 33 is attached to the front end portion 31 to cover the front opening 323 and the rear opening 324.

As shown in FIG. 6, the cover member 33 includes an annular portion 331, a front cover portion 333, and a rear cover portion 334. In this embodiment, the annular portion 331, the front cover portion 333, and the rear cover portion 334 are integrally formed from the same elastic material (e.g., rubber, synthetic resin). In other words, the cover member 33 is configured as a ring-shaped elastic member as a whole.

The annular portion 331 is a loop-shaped band. The annular portion 331 is formed so that it can be attached to the outer periphery of the lower end of the front end portion 31 (specifically, the lower end of the first storage portion 311 and the third storage portion 313) in a slightly pulled state. The front cover portion 333 and the rear cover portion 334 are configured so that they can be fitted into the front opening 323 and the rear opening 324, respectively. The front cover portion 333 and the rear cover portion 334 protrude inward from the inner circumferential surfaces of the front end portion and the rear end portion of the annular portion 331, respectively. The front cover portion 333 is formed in an arc shape that bulges forward. The rear cover portion 334 is formed in an arc shape that bulges backward. The vertical height of the portions of the annular portion 331 that correspond to the front cover portion 333 and the rear cover portion 334 is set to be greater than the height of the front cover portion 333 and the rear cover portion 334.

The operator can easily attach the cover member 33 to the outer periphery of the lower end of the front end 31 while pulling it. As shown in Figs. 4 and 5, when the cover member 33 is attached to the outer periphery of the lower end of the front end 31, the annular portion 331 adheres closely to the outer periphery of the lower end of the front end 31. The front cover portion 333 and the rear cover portion 334 are fitted into the front opening 323 and the rear opening 324 in a slightly compressed state, respectively, to close them. This reduces the possibility of foreign matter (e.g., dust) entering the inner housing 3 from the front opening 323 and the rear opening 324. Furthermore, around the front cover portion 333 and the rear cover portion 334, the annular portion 331 adheres closely to the outer periphery of the lower end of the front end 31. This further effectively reduces the possibility of foreign matter entering.

The front cover part 333 and the rear cover part 334 are biased toward the inside of the front end part 31 (i.e., in the direction of blocking the front opening 323 and the rear opening 324) by the elastic force of the annular part 331. This effectively reduces the possibility that the front cover part 333 and the rear cover part 334 will come off the front opening 323 and the rear opening 324. In addition, because the front cover part 333 and the rear cover part 334 are each formed in an arc shape, the possibility of interference with the operation of the swinging member 536 is reduced.

The clamp mechanism 6 is described below.

The clamp mechanism 6 is a mechanism for holding the tip tool 91 fixedly relative to the tool mounting portion 511 using the clamp shaft 61 and allowing the tip tool 91 to rotate integrally with the spindle 51. Note that the configuration of the clamp mechanism 6 in this embodiment is substantially the same as the configuration of the clamp mechanism disclosed in U.S. Patent Application Publication No. 2020/0282539 (the entirety of which is incorporated by reference). Therefore, a description thereof will be omitted here.

The clamp mechanism 6 is operably connected to a lever 67 that is rotatably supported on the front end 21 of the outer housing 2. In this embodiment, as shown in Figures 4 and 7, the lever 67 is mainly composed of a main body 671, an actuating portion 674, and a torsion coil spring 68.

The main body 671 is rotatably supported by the upper wall 211 of the front end 21 of the outer housing 2 (upper shell 201). The main body 671 is disposed outside the front end 21 and has an operating part 672 that is manually operated by the user. The operating part 674 is disposed above the clamp mechanism 6 within the front end 21 and is fixed to the underside of the main body 671 with a screw 679. The operating part 674 has a pair of operating protrusions 675 that act on the clamp mechanism 6 to operate it.

The torsion coil spring 68 is disposed around the vertical center of the lever 67. One end 681 of the torsion coil spring 68 is engaged with a locking hole (not shown) formed in the upper wall portion 211 of the upper shell 201. The other end 683 of the torsion coil spring 68 is engaged with one of two locking recesses 676 formed in the actuating portion 674. With this configuration, the lever 67 is biased by the torsion coil spring 68 toward an initial position where the operating portion 672 abuts against the left wall portion of the upper shell 201. The reason for providing two locking recesses 676 is to facilitate positioning of the actuating portion 674 relative to the main body portion 671.

The clamping mechanism 6 operates in response to the rotation of the lever 67. Specifically, when the lever 67 is rotated from the initial position in a predetermined direction (clockwise when viewed from above), it operates the clamping mechanism 6 via the operating protrusion 675, releasing the clamping of the tip tool 91. On the other hand, when the lever 67 is rotated from the release position in the opposite direction to when the lock is released, it operates the clamping mechanism 6 via the operating protrusion 675, clamping the tip tool 91.

In this embodiment, the lever 67 and the upper shell 201 are designed to facilitate the assembly of the lever 67 to the upper shell 201. More specifically, as shown in Figs. 4, 7 and 8, two protrusions 677, 678 are provided on both sides of each locking recess 676 of the operating portion 674 in the circumferential direction. The protrusions 677, 678 protrude radially outward. Meanwhile, the upper wall portion 211 of the upper shell 201 is provided with a support hole 212 and a spring accommodating portion 213. The spring accommodating portion 213 is an annular recess provided around the support hole 212. In addition, a relief recess 214 recessed radially outward is provided at one location on the outer edge of the spring accommodating portion 213.

The lever 67 is attached to the upper shell 201 in the following procedure.

First, the worker passes the engagement projection 673, which protrudes from the center of the base of the main body 671, through the support hole 212 of the upper wall 211. At this time, the worker positions the main body 671 relative to the upper shell 201 so that the operating unit 672 is located in the initial position. The worker places the torsion coil spring 68 in the spring housing 213 and fits the end 681 into the locking hole (not shown). The worker then positions the operating unit 674 circumferentially relative to the main body 671, and connects and fixes the operating unit 674 to the main body 671 with the screw 679 so that it cannot rotate.

As shown in FIG. 8, at this stage, the end 683 of the torsion coil spring 68 is not engaged with the locking recess 676 and is positioned radially outward of the operating portion 674. The operator then rotates the lever 67 around the drive axis A1 relative to the upper shell 201 in a counterclockwise direction (the direction of the arrow in FIG. 8) as viewed from the side (below) of the operating portion 674. When the lever 67 is rotated to a predetermined position, as shown in FIG. 9, of the two locking recesses 676, the one closest to the relief recess 214 is positioned facing the relief recess 214.

As shown in FIG. 9, with the lever 67 in a predetermined position, the operator applies a load to the torsion coil spring 68 (winding the torsion coil spring 68 to elastically deform it) and moves the end 683 counterclockwise as viewed from below. The end 683 reaches the relief recess 214, passes through the protrusion 678 within the relief recess 214, and then moves from the relief recess 214 into the locking recess 676. The elastic force of the torsion coil spring 68 biases the operating portion 674 in a clockwise direction as viewed from below (the direction of the arrow in FIG. 9). Thus, the lever 67 rotates with the end 683 locked in the locking recess 676, and is positioned in the initial position.

As described above, in this embodiment, the worker fixes the main body 671 and the operating part 674 in a positioned state, and then rotates the end 683 while rotating the lever 67 a predetermined amount. With this alone, the worker can lock the end 683 in the locking recess 676 and cause the torsion coil spring 68 to bias the lever 67 toward the initial position. This makes it easier to assemble the lever 67 to the upper shell 201 compared to a method in which the end 683 is previously locked to the operating part 674, the main body 671 and the operating part 674 are positioned while applying a load to the torsion coil spring 68, and then the lever 67 is fixed with the screw 679.

The internal structure of the rear end 39 is described below.

As shown in Figures 1 and 2, in this embodiment, the rear portion of the rear end portion 39 is configured as a battery mounting portion 391, and the front portion of the rear end portion 39 is configured as a control unit housing portion 392.

The battery mounting section 391 has an engagement structure that allows the battery 93 to be slidably engaged, and terminals that can be electrically connected to the terminals of the battery 93. Note that the battery mounting section 391 and its structure are well known, so a detailed description will be omitted.

The control unit housing 392 houses the control unit 395. Although detailed illustration is omitted, the control unit 395 includes a three-phase inverter, a control circuit (e.g., a microcomputer with a CPU) that controls the drive of the motor 4 via the three-phase inverter, a board on which these are mounted, and a case that houses the board. The control unit 395 is electrically connected to the battery mounting section 391, the switch unit 26, the motor 4, etc. via electric wires (not shown). The control unit 395 is configured to drive the motor 4 while the switch unit 26 is in the on state.

In addition, by making it possible to attach a battery 93 to the rear end portion 39 of the inner housing 3 and accommodating a control unit 395, the moment of inertia of the inner housing 3 around the drive shaft A1 can be increased, and vibration of the inner housing 3 can be reduced.

The internal structure of the extension portion 35 is described below.

As described above, in this embodiment, the motor 4 and the drive mechanism 5 are disposed in the front end 31, and the control unit 395 and the battery mounting section 391 are provided in the rear end 39. Therefore, although not shown, wires and connection terminals that connect the control unit 395 to the circuit board of the motor 4, etc., are disposed in the extension section 35.

The internal structure of the elastic connecting portion 37 is described below.

1 to 3, the switch holder 25 is disposed in the internal space of the elastic connection part 37 (the space surrounded in the circumferential direction by the elastic member 371). The switch holder 25 is a member configured to hold the switch unit 26. Although the switch holder 25 is disposed in the internal space of the elastic connection part 37, it is fixed to the upper shell 201 and the lower shell 205 and is integrated with the outer housing 2. More specifically, as shown in FIG. 2, the switch holder 25 includes a roughly rectangular box-shaped main body 251 and cylindrical parts 254 provided at the left front end and the right front end of the main body 251, respectively. The cylindrical parts 254 extend in the vertical direction. Although detailed illustration is omitted, the switch holder 25 is fixed to the upper shell 201 and the lower shell 205 by screws inserted into the cylindrical parts 254.

The switch unit 26 will now be described. As shown in FIG. 10, the switch unit 26 of this embodiment includes a first switch 261 and a second switch 262. The first switch 261 is a well-known slide switch configured to open and close a circuit using a slider that can move linearly. The second switch 262 is a well-known microswitch configured to open and close a circuit with a slight movement using a snap action mechanism. The second switch 262 is located to the right of the first switch 261, and the plunger 263 of the second switch 262 protrudes rearward.

As shown in FIG. 1, the switch unit 26 is operably connected to the operating portion 275 via a connecting member 27. The connecting member 27 is a long member that extends linearly in the front-rear direction between the upper shell 201 and the extension portion 35 of the inner housing 3. The front end of the connecting member 27 is connected to the operating portion 275. The rear end of the connecting member 27 is connected to the switch lever 265.

The switch lever 265 is disposed above the first switch 261 and supported by the switch holder 25 (partially omitted in FIG. 10) so as to be movable in the front-rear direction. The switch lever 265 is configured to switch the on/off states of the first switch 261 and the second switch 262 by moving in the front-rear direction between a predetermined on position and an off position in response to a front-rear sliding operation of the operating portion 275. More specifically, the switch lever 265 is connected to a slider (not shown) of the first switch 261. Thus, the slider moves in the front-rear direction together with the switch lever 265. The switch lever 265 also has a pressing piece 266 disposed behind the plunger 263 of the second switch 262.

As shown in FIG. 10, when the switch lever 265 is in the off position, the first switch 261 is in the off state. At this time, the pressing piece 266 is in a position spaced rearward from the plunger 263, and the second switch 262 is also in the off state. On the other hand, as shown in FIG. 11, when the switch lever 265 is in the on position, the first switch 261 is in the on state. At this time, the pressing piece 266 is in a position to press the plunger 263, and the second switch 262 is also in the on state.

In this embodiment, when both the first switch 261 and the second switch 262 are in the on state, the switch unit 26 is in the on state. When at least one of the first switch 261 and the second switch 262 is in the off state, the switch unit 26 is in the off state. As described above, the on/off state of the switch unit 26 is used by the control unit 395 to control the drive of the motor 4.

Because the second switch 262 is a microswitch, there is a possibility that the switch will switch from the on state to the off state in response to a slight movement of the switch lever 265 due to dimensional errors, assembly errors, or even the plunger 263 being biased backwards in the second switch 262 and/or the switch holder 25. In other words, there is a possibility that the on/off state of the switch unit 26 will become unstable. Therefore, in this embodiment, a leaf spring 258 is attached to the switch holder 25 to stably hold the switch lever 265 in the on position.

The leaf spring 258 is disposed below the pressing piece 266 and has a protruding portion 259 that protrudes upward. In the process of the switch lever 265 moving forward from the OFF position shown in FIG. 10, the protruding portion 259 is pressed by the lower end of the pressing piece 266, and the leaf spring 258 bends downward to allow the pressing piece 266 to move forward. As shown in FIG. 11, when the pressing piece 266 passes the protruding portion 259 and the switch lever 265 reaches the ON position, the leaf spring 258 returns upward. With the protruding portion 259 abutting the lower end of the pressing piece 266 from behind, the leaf spring 258 urges the pressing piece 266 forward, and stably holds the switch lever 265 in the ON position. Similarly, when the switch lever 265 moves from the on position to the off position, the leaf spring 258 bends downward to allow the pressing piece 266 to move backward, and when the pressing piece 266 passes the protruding portion 259, it returns upward.

The elastic connection structure between the outer housing 2 and the inner housing 3 will be described below. In this embodiment, the outer housing 2 and the inner housing 3 are elastically connected at multiple locations. Specifically, multiple elastic members are interposed between the front end 21 and the front end 31, and between the switch holder 25 and the rear end 39.

First, we will explain the elastic connection structure between the front end 21 and the front end 31.

As shown in Figures 12 and 13, recesses 317 having a circular cross section are provided on the left and right sides of the first storage section 311 of the front end section 31. The left and right recesses 317 have the same configuration and are arranged symmetrically with respect to the plane P. A cylindrical front elastic member 71 is fitted into each recess 317 in a state where it is slightly compressed in the radial direction. In this embodiment, the front elastic member 71 is made of a urethane resin having an ultrafine foam structure.

In this embodiment, the pair of left and right front elastic members 71 are pressed against the front end portion 31 by the pair of left and right intervening members 28, respectively, and are held in a state of being compressed in the left-right direction. The left and right intervening members 28 are fixed to the outer housing 2 at the left and right sides of the front end portion 31, respectively, in a state of partial contact with the inner surface of the outer housing 2. More specifically, each intervening member 28 is fixed to the upper shell 201 and the lower shell 205. The left and right intervening members 28 have the same configuration and are arranged symmetrically with respect to the plane P.

The detailed configuration of the intervening member 28 will be described below. As shown in Figures 12 to 14, the intervening member 28 includes a first portion 281 that engages with the front elastic member 71 and a second portion 282 that engages with the outer housing 2. The first portion 281 and the second portion 282 are integrally formed from synthetic resin.

The first part 281 includes a disk portion arranged to intersect (more specifically, approximately perpendicular to) a straight line extending in the left-right direction, and a protrusion protruding from the center of the disk portion in a direction approximately perpendicular to the plate surface of the disk portion (approximately in the left-right direction). The protrusion of the first part 281 has an outer diameter slightly larger than the inner diameter of the front elastic member 71. The protrusion is fitted into the center of the front elastic member 71 and is covered by the front elastic member 71 over its entire circumference. The tip of the protrusion is spaced from the bottom surface of the recess 317. The disk portion abuts against one end surface (the surface on the outer housing 2 side) of the front elastic member 71 around the protrusion. In other words, the disk portion has an annular pressing surface 281A. The protrusion of the first part 281 can move relatively within the recess 317 while compressing the front elastic member 71 in any direction, including the up-down direction, the front-back direction, and the left-right direction.

The second portion 282 includes a cylindrical portion 283, a pair of extending portions 284, and a pair of abutting portions 286.

The tubular portion 283 is disposed on the opposite side of the protrusion (the outer housing 2 side) with respect to the disk portion of the first part 281, and extends in the vertical direction from approximately the center of the disk portion to the upper end of the disk portion. The tubular portion 283 is sandwiched from above and below between a cylindrical portion provided on the upper shell 201 and a cylindrical portion provided on the lower shell 205, and is connected to the upper shell 201 and the lower shell 205 by a screw 29 fastened to a screw hole in the cylindrical portion of the lower shell 205. As a result, the intervening member 28 is connected in a state where it is positioned relative to the outer housing 2.

The pair of extensions 284 extend in the up-down direction adjacent to the cylindrical portion 283 on both sides (front and rear) of the cylindrical portion 283. The front and rear extensions 284 have shapes that are symmetrical with respect to the cylindrical portion 283. The extensions 284 are longer than the diameter of the disc portion of the first part 281, and protrude radially outward beyond the upper and lower ends of the disc portion. In other words, the upper and lower ends of the extensions 284 define the upper and lower ends of the intervening member 28.

Of the outer surfaces of the lower end 285 of each extension portion 284, the surface facing the outer housing 2 is inclined toward the inner housing 3 (plane P, first portion 281) as it approaches the lower end. In this embodiment, this surface is inclined in two stages. More specifically, this surface includes a first inclined surface 285A and a second inclined surface 285B that connects to the lower side of the first inclined surface 285A. The inclination angle of the second inclined surface 285B (the angle between the plane P and the second inclined surface 285B) is larger than the inclination angle of the first inclined surface 285A (the angle between the plane P and the first inclined surface 285A). As will be described in detail later, the first inclined surface 285A and the second inclined surface 285B are provided to facilitate the assembly of the intervening member 28 to the outer housing 2.

The pair of abutment portions 286 protrude forward and backward from the pair of extension portions 284, respectively. The abutment portions 286 are provided above the lower ends of the extension portions 284. The lower ends of the abutment portions 286 are also below the upper ends of the lower end portions 285 (more specifically, between the upper and lower ends of the first inclined surface 285A). The abutment portions 286 have an abutment surface 286A that abuts against the inner surface of the outer housing 2 (the right surface of the left wall portion or the left surface of the right wall portion of the outer housing 2). The abutment surface 286A is a surface that intersects with a straight line extending in the left-right direction (more specifically, a surface that is approximately perpendicular). The abutment surface 286A is also approximately parallel to the pressing surface 281A of the first portion 281. Additionally, the abutment surface 286A and the pressing surface 281A are positioned so that they partially overlap in the left-right direction (i.e., a portion of the abutment surface 286A and a portion of the pressing surface 281A are on the same straight line extending in the left-right direction).

The following describes how to assemble the front elastic member 71 and the interposition member 28 to the housing 10.

First, the worker fits the front elastic member 71 into the left and right recesses 317 of the front end portion 31 of the inner housing 3. Next, the worker fits the protrusion of the first part 281 of the intervening member 28 into the front elastic member 71. The intervening member 28 is held in place by the elastic force of the front elastic member 71 and is provisionally connected to the inner housing 3 via the front elastic member 71 (see FIG. 3). Thus, the worker can handle the inner housing 3, the front elastic member 71, and the intervening member 28 as a single unit.

The worker places the inner housing 3 in this state inside the lower shell 205, which is placed on the workbench so that it opens upward. The upper left and right wall portions of the lower shell 205 are provided with recesses 206 having shapes that roughly correspond to the cylindrical portion 283 and the pair of extending portions 284, respectively. The worker aligns the cylindrical portion 283 and the pair of extending portions 284 with the recesses 206, and moves the inner housing 3 downward relative to the lower shell 205.

The first part of the intervening member 28 to enter the lower shell 205 is the lower end of the pair of extending portions 284, i.e., the lower end of the portion where the second inclined surface 285B is provided. This reduces the possibility that the lower end of the intervening member 28 will interfere with the upper end of the lower shell 205 when the intervening member 28 enters the lower shell 205. The worker can easily insert the lower end 285 into the lower shell 205 (specifically, the recess 206). Following the portion of the lower end 285 where the second inclined surface 285B is provided, the portion where the first inclined surface 285A is provided also smoothly enters the lower shell 205 (recess 206).

When the worker further moves the inner housing 3 downward relative to the lower shell 205, the abutment surface 286A of the abutment portion 286 abuts against the inner surface of the lower shell 205 (specifically, the protruding end surfaces of the pair of ribs 207 that define the recess 206). In this state, when the worker further moves the inner housing 3 downward relative to the lower shell 205, the front elastic member 71 is pressed against the inner housing 3 and is compressed in the left-right direction. When the lower end of the tubular portion 283 roughly reaches a position where it abuts against the upper end of the cylindrical portion of the lower shell 205, the operation of accommodating the inner housing 3 in the lower shell 205 is completed. The worker places the upper shell 201 on the upper side of the lower shell 205 and tightens the screw 29. This completes the assembly of the front elastic member 71 and the interposition member 28 to the housing 10.

As described above, the intervening member 28 having the lower end 285 with the first inclined surface 285A and the second inclined surface 285B facilitates the operation of inserting the front elastic member 71 into the inner housing 3 and the lower shell 205 while compressing it in the left-right direction.

In addition, when the intervening member 28 is assembled to the inner housing 3 and the lower shell 205, the abutment surface 286A, which is different from the first inclined surface 285A and the second inclined surface 285B, is configured to abut against the inner surface of the lower shell 205 (specifically, the protruding end surfaces of the pair of ribs 207 that define the recess 206). Therefore, by ensuring the dimensional accuracy of the abutment surface 286A and the rib 207 of the outer housing 2, the front elastic member 71 can be properly supported, which makes it easy to manufacture the intervening member 28. In this embodiment, when the intervening member 28 is assembled to the inner housing 3 and the lower shell 205, the first inclined surface 285A and the second inclined surface 285B do not substantially abut against the inner surface of the lower shell 205 (the surface that defines the recess 206), but may abut against it.

The elastic connection structure between the switch holder 25 and the rear end 39 is described below.

As shown in FIG. 2, the left and right walls of the body 251 of the switch holder 25 each have a recess 252 recessed inward (toward plane P). The left and right recesses 252 have the same configuration and are arranged symmetrically with respect to plane P. A rear elastic member 73 is fitted into the recess 252. The rear elastic member 73, like the front elastic member 71, is made of a urethane resin with an ultrafine foam structure.

On the other hand, a pair of arms 393 protrude forward from the left and right walls of the rear end 39 (control unit housing 392) of the inner housing 3. A protrusion protruding inward (plane P) is provided at the tip of each arm 393. The tip of the arm 393 contacts the outer surface of the rear elastic member 73, and the protrusion is fitted into a recess provided in the rear elastic member 73 and is covered by the rear elastic member 73 over the entire circumference. The tip of the protrusion of the arm 393 is separated from the bottom of the recess 252. With this configuration, the tip of the arm 393 can move relatively within the recess 252 while compressing the rear elastic member 73 in any direction, including the up-down direction, the front-rear direction, and the left-right direction.

As described above, in this embodiment, the outer housing 2 and the inner housing 3 are connected via the front elastic member 71 and the rear elastic member 73 in a state in which they can move relative to each other in all directions. This configuration effectively reduces the transmission of vibration from the inner housing 3 to the outer housing 2 when the tool tip 91 is driven to oscillate.

Furthermore, in this embodiment, as shown in Figs. 1 to 3, the rear end 39 of the inner housing 3 and the rear end 23 of the outer housing 2 are provided with restricting portions 8 for restricting movement of the inner housing 3 relative to the outer housing 2. In this embodiment, the restricting portions 8 include four restricting portions: an upper restricting portion 81, a lower restricting portion 82, a left restricting portion 83, and a right restricting portion 84. Each of the upper restricting portion 81, the lower restricting portion 82, the left restricting portion 83, and the right restricting portion 84 includes a pair of abutting portions (more specifically, a recessed portion and a protruding portion) that can abut against each other.

The upper regulating portion 81 includes a recess 811 provided on the upper wall portion of the rear end portion 23 and a protrusion 815 provided on the upper wall portion of the rear end portion 39. The recess 811 is recessed upward from the lower surface of the upper wall portion of the rear end portion 23. The recess 811 is formed as a groove extending in the left-right direction from approximately the left end to the right end of the upper wall portion of the rear end portion 23. The recess 811 has a substantially rectangular cross section and is defined by a front surface, a rear surface, and an upper surface. The protrusion 815 is an elongated protrusion that protrudes upward from the upper surface of the upper wall portion of the rear end portion 39 and extends in the left-right direction. The protrusion 815 is provided in the center of the upper wall portion of the rear end portion 39 in the left-right direction. The protrusion 815 has a substantially rectangular cross section and has a front surface, a rear surface, and an upper surface.

The protrusion 815 is disposed in the recess 811. A gap is provided between the tip of the protrusion 815 and the bottom surface (upper surface) of the recess 811. The width of the recess 811 in the front-rear direction is set to be larger than the width of the protrusion 815 in the front-rear direction, and in the initial state in which the outer housing 2 and the inner housing 3 are not moving relative to each other, a gap exists between the front and rear sides of the protrusion 815. On the other hand, when the rear end 23 and the rear end 39 move relative to each other, a part of the protrusion 815 abuts against the surface that defines the recess 811, so that the relative movable range of the rear end 23 and the rear end 39 is limited. More specifically, the gap between the front surface of the protrusion 815 and the front surface of the recess 811 defines the range in which the upper end of the rear end 39 can move forward relative to the upper end of the rear end 23. The gap between the rear surface of the protrusion 815 and the rear surface of the recess 811 defines the range in which the upper end of the rear end 39 can move backward relative to the upper end of the rear end 23.

The left-right gap between the tip of the protrusion 815 and the bottom surface of the recess 811, the gap between the front surface of the protrusion 815 and the front surface of the recess 811, and the gap between the rear surface of the protrusion 815 and the rear surface of the recess 811 are all smaller than the gap between the outer surface of the other parts of the inner housing 3 (i.e., the front end 31, the extension 35, and the elastic connecting portion 37) and the inner surface of the outer housing 2. Furthermore, all of these gaps are set so that the inner housing 3 does not come into contact with the outer housing 2 even if the inner housing 3 vibrates when the tip tool 91 is driven to oscillate.

The lower regulating portion 82 includes a recess 821 provided in the lower wall portion of the rear end portion 23 and a protrusion 825 provided in the lower wall portion of the rear end portion 39. The recess 821 is recessed downward from the upper surface of the lower wall portion of the rear end portion 23. The recess 821 is formed as a groove extending in the left-right direction from approximately the left end to the right end of the lower wall portion of the rear end portion 23. The recess 821 has a substantially rectangular cross section and is defined by a front surface, a rear surface, and a lower surface. The protrusion 825 is an elongated protrusion that protrudes downward from the lower surface of the lower wall portion of the rear end portion 39 and extends in the left-right direction. The protrusion 825 is provided in the center of the lower wall portion of the rear end portion 39 in the left-right direction. The protrusion 825 has a substantially rectangular cross section and has a front surface, a rear surface, and a lower surface. In this embodiment, the lower regulating portion 82 is disposed at a different position from the upper regulating portion 81 (specifically, rearward of the upper regulating portion 81), but may be disposed at approximately the same position as the upper regulating portion 81 in the front-rear direction.

The protrusion 825 is disposed within the recess 821. A gap is provided between the tip of the protrusion 825 and the bottom surface (lower surface) of the recess 821. The front-to-rear width of the recess 821 is set to be larger than the front-to-rear width of the protrusion 825, and in the initial state, a gap exists between the front and rear sides of the protrusion 825. As with the upper restricting portion 81, the protrusion 825 and the recess 821 abut against each other to limit the relative movable range of the rear end 23 and the rear end 39. The setting of the gap between the protrusion 825 and the recess 821 is the same as that of the upper restricting portion 81.

The left side regulating portion 83 includes a recess 831 provided on the left wall of the rear end portion 23 and a protrusion 835 provided on the left wall of the rear end portion 39. The recess 831 is recessed leftward from the right surface of the left wall of the rear end portion 23. The recess 831 is formed as a groove extending in the vertical direction from approximately the upper end to the lower end of the left wall of the rear end portion 23. The recess 831 has a substantially rectangular cross section and is defined by a front surface, a rear surface, and a left surface. The protrusion 835 is an elongated protrusion that protrudes leftward from the left surface of the left wall of the rear end portion 39 and extends in the vertical direction. The protrusion 835 is provided in the center of the left wall of the rear end portion 39 in the vertical direction. The protrusion 835 has a substantially rectangular cross section and has a front surface, a rear surface, and a left surface.

The protrusion 835 is disposed within the recess 831. A gap is provided between the tip of the protrusion 835 and the bottom surface (left surface) of the recess 831. The front-to-rear width of the recess 831 is set to be greater than the front-to-rear width of the protrusion 835, and in the initial state, a gap exists between the front and rear sides of the protrusion 835. As with the upper restricting portion 81, the protrusion 835 and the recess 831 abut against each other to limit the relative movable range of the rear end 23 and the rear end 39. The setting of the gap between the protrusion 835 and the recess 831 is the same as that of the upper restricting portion 81.

The right side regulating portion 84 includes a recess 841 provided in the right wall portion of the rear end portion 23 and a protrusion 845 provided in the right wall portion of the rear end portion 39. The recess 841 is recessed to the right from the left surface of the right wall portion of the rear end portion 23. The recess 841 is formed as a groove extending in the vertical direction from approximately the upper end to the lower end of the right wall portion of the rear end portion 23. The recess 841 has a substantially rectangular cross section and is defined by a front surface, a rear surface, and a right surface. The protrusion 845 is an elongated protrusion that protrudes to the right from the right surface of the right wall portion of the rear end portion 39 and extends in the vertical direction. The protrusion 845 is provided in the center of the right wall portion of the rear end portion 39 in the vertical direction. The protrusion 845 has a substantially rectangular cross section and has a front surface, a rear surface, and a right surface. In this embodiment, the right-side regulating portion 84 is disposed at approximately the same position as the left-side regulating portion 83 in the front-rear direction, but may be disposed at a different position from the left-side regulating portion 83 in the front-rear direction.

The protrusion 845 is disposed within the recess 841. A gap is provided between the tip of the protrusion 845 and the bottom surface (right surface) of the recess 841. The front-to-rear width of the recess 841 is set to be larger than the front-to-rear width of the protrusion 845, and in the initial state, a gap exists between the front and rear sides of the protrusion 845. As with the upper restricting portion 81, the protrusion 845 and the recess 841 abut against each other to limit the relative movable range of the rear end 23 and the rear end 39. The setting of the gap between the protrusion 845 and the recess 841 is the same as that of the upper restricting portion 81.

The restricting portion 8 having the above-described configuration restricts the range of movement of the rear end portion 39 of the inner housing 3 relative to the outer housing 2 compared to other portions not provided with a restricting portion (i.e., the front end portion 31, the extension portion 35, and the elastic connecting portion 37). If the vibration tool 1 is dropped, a portion of the protrusion of at least one of the upper restricting portion 81, the lower restricting portion 82, the left restricting portion 83, and the right restricting portion 84 comes into contact with a surface that defines the recess, restricting the movement of the inner housing 3 relative to the outer housing 2. This reduces the possibility that the inner housing 3 will move significantly relative to the outer housing 2 due to inertia.

In particular, in this embodiment, an upper restricting portion 81, a lower restricting portion 82, a left restricting portion 83, and a right restricting portion 84 are provided at four circumferential positions on the outer housing 2 and the inner housing 3. Therefore, movement of the inner housing 3 relative to the outer housing 2 can be more reliably restricted compared to when restricting portions are provided at only one circumferential position.

In the vibration tool 1, the spindle 51 that swings the tool tip 91 is the main vibration source. The rear end 39 is the farthest part of the inner housing 3 from the drive shaft A1, so the vibration of the rear end 39 tends to be greater than the vibration of other parts closer to the drive shaft A1 (i.e., the front end 31, the extension 35, and the elastic connection 37). Therefore, it is reasonable to restrict the movement of the inner housing 3 relative to the outer housing 2 at the rear end 39. In this embodiment, the elastic connection 37 effectively reduces the vibration transmission from the extension 35 to the rear end 39. Therefore, the vibration at the rear end 39 is smaller than when the elastic connection 37 is not provided, but even in such a case, it is reasonable to provide the restriction portion 8 at the rear end 39 and the rear end 23. In this embodiment, the restricting portion 8 avoids the possibility of impeding the relative movement of the inner housing 3 with respect to the outer housing 2 when the tool tip 91 is driven to oscillate, while realizing a vibration-proof structure that can reduce the impact on the inner housing 3 when the vibration tool 1 is dropped.

The elastic member 371 of the elastic connecting portion 37 is more susceptible to damage when an impact is applied in the front-rear direction than other portions of the inner housing 3. In contrast, the restricting portion 8 is configured to restrict the front-rear movement of the inner housing 3 relative to the outer housing 2, and therefore can effectively respond to cases where the vibration tool 1 is dropped from the rear end portion 39 or the front end portion 31, thereby reducing the possibility of damage to the elastic member 371.

Furthermore, the upper regulating portion 81, the lower regulating portion 82, the left regulating portion 83, and the right regulating portion 84 are each composed of a recess and a protruding portion disposed within the recess. Therefore, by a part of the protruding portion abutting against a surface that defines the recess, it is possible to regulate not only the linear movement forward and backward of the inner housing 3 relative to the outer housing 2, but also its rotation.

The correspondence between each component of the above embodiment and each component of this disclosure or the present invention is shown below. However, each component of the embodiment is merely an example and does not limit each component of the present invention.

The vibration tool 1 is an example of an "electric tool". The motor 4 and the output shaft 413 are an example of a "motor" and an "output shaft", respectively. The spindle 51 is an example of a "spindle". The oscillating member 536 is an example of an "oscillating member". The housing 10 (inner housing 3) is an example of a "housing". The front opening 323 and the rear opening 324 are an example of a "first opening" and a "second opening", respectively. The front cover portion 333 and the rear cover portion 334 are an example of a "first cover portion" and a "second cover portion", respectively. The cover member 33 is an example of a "cover member".

The above embodiment is merely an example, and the power tool according to the present invention is not limited to the vibration tool 1 illustrated. For example, the following modifications can be made. At least one of these modifications can be adopted in combination with the vibration tool 1 illustrated in the embodiment and at least one of the features described in the claims.

The elastic connection structure between the outer housing 2 and the inner housing 3 may be modified as appropriate. For example, the front elastic member 71 and the rear elastic member 73 may each be formed of a material (e.g., rubber, a spring element, or a different type of synthetic resin) different from that in the above embodiment. The number, shape, and arrangement of the front elastic member 71 and the rear elastic member 73 may be modified as appropriate. In addition, the front elastic member 71 and the rear elastic member 73 may each be held between the inner housing 3 and a member other than the interposition member 28 and the switch holder 25 that is integrated with the outer housing 2. Alternatively, the front elastic member 71 and the rear elastic member 73 may each abut against the inner housing 3 and the outer housing 2.

At least one of the upper regulating portion 81, the lower regulating portion 82, the left regulating portion 83, and the right regulating portion 84 may be omitted. Alternatively, one regulating portion may be provided that extends around the entire circumference of the rear end portion 39 and the rear end portion 23. The arrangement of the regulating portion 8 may also be changed. For example, in an inner housing 3 that does not have an elastic connecting portion 37, the regulating portion 8 may be provided at the rear end of the extending portion 35 (i.e., the portion of the extending portion 35 that is farthest from the drive shaft A1). The configuration of each of the upper regulating portion 81, the lower regulating portion 82, the left regulating portion 83, and the right regulating portion 84 may also be appropriately changed, such as by reversing the arrangement of the recess and the protrusion.

The outer housing 2 may be formed by connecting a right shell and a left shell instead of the upper shell 201 and the lower shell 205, for example. Also, the switch holder 25 does not necessarily have to be connected to the outer housing 2. Similarly, the shapes and components of the metal housing 301 and the resin housing 305 constituting the inner housing 3, as well as the connection mode of the metal housing 301 and the resin housing 305, may be changed as appropriate. For example, the elastic connection portion 37 of the inner housing 3 may be omitted, and the extension portion 35 and the rear end portion 39 may be directly connected.

Furthermore, the housing 10 does not necessarily have to have a vibration-proof structure as in the above embodiment. For example, the housing 10 may be a housing with a single-layer structure. Alternatively, the housing 10 may have a structure in which an inner housing is fixedly disposed within an outer housing.

The shape, dimensions, and arrangement of the front opening 323 and the rear opening 324 may be changed as appropriate, for example, depending on the configuration and arrangement of the swinging member 536, or regardless of this. For example, the vertical dimensions and positions of the front opening 323 and the rear opening 324 may be the same. Correspondingly, the configuration and positions of the front cover portion 333 and the rear cover portion 334 of the cover member 33 are also changed.

Furthermore, the front cover part 333 and the rear cover part 334 do not need to be connected to each other, and may be different members separated from each other. Alternatively, the front cover part 333 and the rear cover part 334 may be connected to both ends of a band-shaped member, respectively, instead of the annular part 331. Furthermore, the front cover part 333 and the rear cover part 334 may be made of elastic bodies made of different materials, or may be made of a material other than an elastic body.

The configuration of the internal mechanism including the motor 4, drive mechanism 5, clamp mechanism 6, and control unit 395, the configuration of the members supported by the outer housing 2 (e.g., lever 67, connecting member 27), and the arrangement of these may also be changed as appropriate. For example, the motor 4 may be an AC motor or a motor with brushes. The motor 4 may also be disposed within the gripping portion 22 so that the rotation axis A2 of the output shaft 413 is perpendicular to the drive axis A1.

Furthermore, in consideration of the spirit of the present invention and the above-mentioned embodiment and its modified examples, the following aspects are constructed. At least one of the following aspects may be employed alone or in combination with at least one of the features described in the claims, the vibration tool 1 of the above-mentioned embodiment, the modified examples, and the claims.
[Aspect 1]
At least one of the first opening and the second opening is configured to allow the pivoting member to pass therethrough.
[Aspect 2]
The housing has a third opening that opens in the first direction on the rotation shaft, and a fourth opening that opens in the first direction on the drive shaft.
The upper end of the second accommodating portion 312 and the lower end of the first accommodating portion 311 are examples of a "third opening" and a "fourth opening", respectively.
[Aspect 2]
the first direction and the second direction define an up-down direction and a front-rear direction of the power tool, respectively;
The housing includes:
a first portion that accommodates the spindle and a portion of the rocking member;
a second portion disposed on a rear side of the first housing portion and housing the motor;
a third housing portion disposed behind the first portion and below the second housing portion and configured to house a portion of the swing member;
The first opening is provided in a front wall of the first housing portion, and the second opening is provided in a rear wall of the third housing portion.
The first storage portion 311, the second storage portion 312, and the third storage portion 313 are examples of the "first portion," the "second portion," and the "third portion," respectively.
[Aspect 3]
The power tool further includes two bearings that are held in the housing at positions spaced apart from each other in the first direction and rotatably support the spindle.
The first opening is provided in a region of the housing between the two bearings in the first direction.
The bearings 513 and 514 are an example of the "two bearings."
[Aspect 4]
The power tool comprises:
an eccentric shaft coaxially connected to the output shaft and having an eccentric portion;
a drive bearing attached to an outer periphery of the eccentric portion and operably connected to the rocker member;
The second opening is provided in a region of the housing that corresponds to at least a portion of the eccentric shaft in the first direction.
The eccentric shaft 531 and the drive bearing 534 are examples of the "eccentric shaft" and the "drive bearing", respectively.
[Aspect 5]
The swing member has a first end fixed to the spindle and a bifurcated second end abutting against an outer circumferential surface of the drive bearing,
The dimension of the first end in the first direction is greater than the dimension of the second end in the first direction.
The first end 537 and the second end 538 are examples of the "first end" and the "second end", respectively.
[Aspect 6]
The first end of the swing member abuts against the first bearing, of the two bearings, which is closer to the tool bit.
The bearing 514 is an example of a "first bearing."
[Aspect 7]
The single cover member is formed in an annular shape and is removably attached to the housing around the accommodating portion for the swinging member.

1: vibration tool, 10: housing, 2: outer housing, 201: upper shell, 205: lower shell, 206: recess, 207: rib, 21: front end, 211: upper wall, 212: support hole, 213: spring accommodating section, 214: relief recess, 215: opening, 22: center (grip section), 23: rear end, 25: switch holder, 251: main body, 252: recess, 254: cylindrical section, 258: leaf spring, 259: protrusion, 26: switch unit, 261: first switch, 262: second switch, 263: plunger, 265: switch lever, 266: pressure piece, 27: connecting member, 275: Operating portion, 28: intervening member, 281: first portion, 281A: pressing surface, 282: second portion, 283: cylindrical portion, 284: extending portion, 285: lower end portion, 285A: first inclined surface, 285B: second inclined surface, 286: abutting portion, 286A: abutting surface, 29: screw, 3: inner housing, 301: metal housing, 305: resin housing, 306: right shell, 307: left shell, 31: front end portion, 311: first housing portion, 312: second housing portion, 313: third housing portion, 314: cover portion, 317: recess, 323: front opening, 324: rear opening, 33: cover member, 331: annular portion, 333: front side Cover portion, 334: rear cover portion, 35: extension portion, 351: outer extension portion, 353: inner extension portion, 37: elastic coupling portion, 371: elastic member, 39: rear end portion, 391: battery mounting portion, 392: control unit housing portion, 393: arm portion, 395: control unit, 4: motor, 413: output shaft, 45: fan, 5: drive mechanism, 6: clamp mechanism, 8: restriction portion, 51: spindle, 511: tool mounting portion, 513: bearing, 514: bearing, 53: transmission mechanism, 531: eccentric shaft, 534: drive bearing, 536: swing member, 537: first end portion, 538: second end portion, 61: clamp shaft Shaft, 67: Lever, 671: Main body, 672: Operation part, 673: Engagement protrusion, 674: Actuation part, 675: Actuation protrusion, 676: Locking recess, 677: Protrusion, 678: Protrusion, 679: Screw, 68: Coil spring, 681: End, 683: End, 71: Front elastic member, 73: Rear elastic member, 81: Upper regulating part, 811: Recess, 815: Protrusion, 82: Lower regulating part, 821: Recess, 825: Protrusion, 83: Left regulating part, 831: Recess, 835: Protrusion, 84: Right regulating part, 841: Recess, 845: Protrusion, 91: Tip tool, 93: Battery, A1: Drive shaft, A2: Rotation shaft, P: Plane

Claims (8)

A power tool,
a motor having an output shaft rotatable about a rotation axis extending in a first direction;
a spindle configured to be able to mount a tool tip and rotatable about a drive shaft extending parallel to the rotation shaft;
a swing member operatively connected to the output shaft and the spindle, configured to swing about the drive shaft in response to rotation of the output shaft, thereby causing the spindle to rotate back and forth about the drive shaft;
a housing that accommodates the motor, the spindle, and the oscillating member, the housing having a first opening and a second opening that are provided on both sides of the oscillating member in a second direction in which a straight line perpendicular to the rotation axis of the output shaft and the drive shaft extends , the first opening and the second opening allowing the oscillating member to be inserted into the housing when assembling the power tool ;
a first cover portion that closes the first opening;
and a second cover portion that covers the second opening. The power tool according to claim 1, wherein each of the first cover part and the second cover part is made of an elastic material. The power tool according to claim 1 or 2, wherein the first cover part and the second cover part are connected to each other to form a single cover member. The power tool according to claim 3, wherein the entire single cover member is made of the same material. the single cover member is formed in an annular shape and is removably attached to the housing around a accommodating portion of the swinging member,
The power tool according to claim 3 or 4, wherein the first cover portion and the second cover portion are biased in a direction to close the first opening and the second opening, respectively. The power tool according to any one of claims 1 to 5, wherein the first opening is positioned on the opposite side of the spindle from the output shaft in the second direction, and the dimension of the first opening in the first direction is greater than the dimension of the second opening in the first direction. The power tool according to claim 6, wherein the center of the first opening in the first direction and the center of the second opening in the first direction are offset in the first direction. An electric power tool according to any one of claims 1 to 7, wherein at least one of the first cover part and the second cover part faces the inside of the housing and has an arc-shaped surface that bulges in a direction away from the spindle and the oscillating member housed in the housing .

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