JP6904145B2 - Electric tool - Google Patents

Description

The present invention relates to a power tool.

Conventionally, an electric tool having a main body to which a tip tool can be attached and detached and a handle connected to the main body, and applying a striking force (or rotational force and striking force) to the tip tool to crush the work material has been widely known. ing. As such a power tool, when a large vibration is generated in the main body during crushing work, a tip tool is used between the handle and the main body in order to suppress the vibration from being transmitted from the main body to the operator who grips the handle. There is known a striking tool provided with a vibration reduction mechanism capable of absorbing vibration in the axial direction of the above (see Patent Document 1).

In a striking tool having the vibration reduction mechanism, when vibration in the axial direction of the tip tool occurs, the handle and the main body rotate relative to each other around a single shaft provided on the handle and vibrate. By absorbing the vibration by the reduction mechanism, it is suppressed that the vibration in the axial direction of the tip tool is transmitted to the operator.

Japanese Unexamined Patent Publication No. 2017-13173

However, when the handle and the main body rotate relative to each other around a single shaft provided on the handle, an excessive load is applied to the shaft, and the handle may be damaged.

Therefore, an object of the present invention is to provide an electric tool capable of easily distributing a load due to relative rotation between a handle and a main body.

In order to solve the above problems, the present invention has a main body housing and a handle that is connected to the main body housing by abutting and connecting the first and second portions of the half-split shape to each other. The first portion and the second portion have a rotation allowance portion that is rotatably connected to the main body housing while accommodating a part of the main body housing, and the rotation allowance portion is the first portion. A blocking portion that prevents the second portion and the second portion from moving close to each other in the butt direction, and a blocking portion that is located radially outside the blocking portion and is slidable on a part of the main body housing. A guide portion having a sliding surface for guiding the rotation of the handle with respect to the main body housing around the axis of the main body housing, and the position of the blocking portion with respect to the handle of the main body housing in the radial direction is described. Provided is a power tool characterized by being positioned by a sliding surface.

The power tool having the above configuration has a sliding surface that guides the rotation of the handle with respect to the main body housing, in addition to the blocking portion that prevents the first portion and the second portion of the handle from moving close to each other in the butt direction. Since the guide portion is provided, the load applied to the blocking portion is reduced as compared with the case where the load due to rotation is directly applied to the blocking portion. Further, since the radial position of the blocking portion with respect to the handle of the main body housing is positioned by the sliding surface, the handle and the main body housing can be suitably rotated relative to each other.

In the above configuration, the rotation permitting portion further has a regulating portion located between the sliding surface and the blocking portion in the radial direction of the blocking portion, and the regulating portion is a part of the main body housing. It is preferable to regulate the relative movement of the handle and the main body housing in the axial direction of the rotation by sandwiching the butt in the butt direction.

According to such a configuration, it is possible to preferably regulate the relative movement of the handle and the main body housing in the axial direction of rotation.

Further, the handle further has a handle main body portion connected to the guide portion, the blocking portion and the restricting portion are connected, the regulating portion and the guide portion are connected, and the blocking portion and the blocking portion are connected. It is preferable that the connection portion with the regulation portion, the connection portion between the regulation portion and the guide portion, and the connection portion between the guide portion and the handle main body portion each have a predetermined curvature.

According to such a configuration, the strength of the connection portion can be increased, and it is possible to prevent the handle from being damaged.

Further, it is preferable that the guide portion is formed in a cylindrical shape concentric with the blocking portion, and the sliding surface is defined by the outer circumference of the guide portion over the entire circumference in the circumferential direction of the guide portion.

According to such a configuration, the handle can be suitably rotated with respect to the main body housing.

Further, the guide portion has a cross-sectional shape in a virtual plane orthogonal to the axis of the blocking portion, forming a quadrangle formed by a pair of straight portions facing each other and a pair of arc portions facing each other, and is a part of the main body housing. Provided a space defined by a pair of arcuate surfaces that slide in front of the pair of arcuate portions and a pair of planes that face and abut against the pair of straight portions, and the pair of arcuate surfaces. It is preferable that the connecting portion with the pair of planes is recessed outward in the radial direction of the blocking portion to allow relative rotation between the handle and the main body housing.

According to such a configuration, the handle housing 3 and the main body housing 2 can be rotated by a predetermined amount due to the recess of the connecting portion. The handle does not rotate more than a predetermined amount with respect to the main body housing due to the contact between the straight portion of the guide portion and the flat surface of the main body housing, and there is no need to provide another member for restricting the rotation. It is possible to reduce the points.

Further, it is preferable that the rotation permitting portion is integrally provided in the first portion and the second portion of the handle.

With such a configuration, it is possible to reduce the number of parts.

Further, it further has a motor supported by the main body housing and an output shaft portion supported by the main body housing and driven by the rotational force of the motor, and the handle and the main body housing are of the output shaft portion. It is preferable that they are connected via a vibration reducing portion that reduces axial vibration.

According to such a configuration, the handle rotates with respect to the main body housing, and the vibration reduction mechanism reduces the axial vibration of the output shaft portion, so that the operator can receive the axial vibration of the output shaft portion. Transmission is reduced.

Further, the motor has a rotary shaft, and the output shaft portion is configured so that the tip tool can be attached and detached, and the rotary motion of the rotary shaft is converted into a reciprocating motion to reciprocate the tip tool in a predetermined direction. It is preferable to further have a power transmission unit capable of the above.

According to such a configuration, in an electric tool such as a hammer that vibrates in the main body, the handle rotates with respect to the main body housing, and the vibration reduction mechanism reduces the axial vibration of the output shaft. This reduces the transmission of axial vibration of the output shaft to the operator.
The present invention further comprises a main body housing and a handle that is connected to the main body housing by butt-joining the first and second portions of the half-split shape to the main body housing, the first portion and the second portion. Means that the rotation permitting portion is rotatably connected to the main body housing, and the rotation permitting portion is such that the first portion and the second portion abut against each other in the abutting direction. A columnar blocking portion that prevents proximity movement and a handle-side sliding that is located on the radial outer side of the blocking portion and guides the rotation of the handle with respect to the main body housing around the axis of the blocking portion. The main body housing has a guide portion having a surface, and the main body housing has a main body side sliding surface that slides with respect to the handle side sliding surface, and the main body with respect to the handle in the radial direction of the blocking portion. The position of the housing is positioned by abutting the sliding surface on the main body side with the sliding surface on the handle side, and the distance between the blocking portion and the housing on the main body is the sliding surface on the handle side and the sliding surface. Provided is an electric tool characterized in that it is larger than the distance from the sliding surface on the main body side.
The present invention further comprises a main body housing and a handle that is connected to the main body housing by butt-joining the first and second portions of the half-split shape to the main body housing, the first portion and the second portion. Means that the rotation permitting portion is rotatably connected to the main body housing, and the rotation permitting portion is such that the first portion and the second portion abut against each other in the abutting direction. A columnar blocking portion that prevents proximity movement and a sliding surface that is located radially outside the blocking portion and guides the rotation of the handle with respect to the main body housing about the axis of the blocking portion. The position of the main body housing with respect to the handle in the radial direction of the blocking portion is positioned by the sliding surface, and the guide portion is orthogonal to the axis of the blocking portion. The cross-sectional shape in the virtual plane is a quadrangle composed of a pair of straight lines facing each other and a pair of arcs facing each other, and a part of the main body housing is a pair that slides facing the pair of arcs. The arc surface is provided with a space defined by a pair of planes facing and abutting the pair of straight portions, and the connecting portion between the pair of arc surfaces and the pair of planes is in the radial direction of the blocking portion. Provided is an electric tool characterized in that it is recessed outward to allow relative rotation between the handle and the main body housing.

According to the power tool of the present invention, it is possible to easily disperse the load due to the relative rotation between the handle and the main body.

It is sectional drawing side view of the hammer which concerns on 1st Embodiment of this invention. FIG. 2 is a cross-sectional view taken along the line II-II of FIG. 1, showing an engagement relationship between a rotation permitting portion and a rotating portion. FIG. 2 is a cross-sectional view taken along the line III-III of FIG. 2, showing the engagement relationship between the rotation permitting portion and the rotating portion. It is sectional drawing side view of the hammer which concerns on 2nd Embodiment of this invention. FIG. 4 is a sectional view taken along line VV of FIG. 4, showing an engagement relationship between a rotation permitting portion and a rotating portion. FIG. 4 is a sectional view taken along line VI-VI of FIG. 4, showing an engagement relationship between a rotation permitting portion and a rotating portion. FIG. 6 is a cross-sectional view taken along the line VII-VII of FIG. 6, showing the engagement relationship between the rotation permitting portion and the rotating portion.

The hammer 1, which is an example of the power tool according to the first embodiment of the present invention, will be described with reference to FIGS. 1 to 3. The hammer 1 is an electric striking tool for crushing a work material (for example, concrete or the like) by applying a striking force.

In the following description, "up" shown in FIG. 1 is defined as an upward direction, "down" is defined as a downward direction, "front" is defined as a forward direction, and "rear" is defined as a backward direction. Further, when the hammer 1 is viewed from the rear, "right" is defined as the right direction, and "left" is defined as the left direction. When the dimensions, numerical values, etc. are referred to in the present specification, not only the dimensional values that completely match the dimensions, numerical values, etc., but also the dimensions, numerical values, etc. that substantially match (for example, when it is within the range of manufacturing error). Shall include. Similarly for "identical", "orthogonal", "parallel", "match", "plane", etc., "substantially identical", "substantially orthogonal", "substantially parallel", "substantially match", "substantially flush" Etc. shall be included.

As shown in FIG. 1, the hammer 1 mainly includes a main body housing 2, a handle housing 3, a motor 4, a power transmission unit 5, and an output unit 6.

The main body housing 2 has a motor housing 21 and a gear housing 22. The main body housing 2 is an example of the "main body housing" in the present invention.

The motor housing 21 has a substantially cylindrical shape extending in the vertical direction, and houses the motor 4. The motor housing 21 has a connecting portion 21A and a rotating portion 23.

The connecting portion 21A forms the rear portion of the lower portion of the motor housing 21 and extends in the front-rear direction.

The rotating portion 23 extends rearward from the rear portion of the connecting portion 21A. The details of the rotating portion 23 will be described later. The rotating portion 23 in the drawing is shown by hatching from the upper right to the lower left.

The motor 4 is a brushed AC motor and has a rotating shaft 41.

The rotating shaft 41 is rotatably supported by the main body housing 2 via a bearing. A fan 41A is fixed to the rotary shaft 41 so as to be integrally rotatable with the rotary shaft 41 on the upper portion of the rotary shaft 41. The motor 4 may be a brushless motor.

The gear housing 22 is made of metal and, as shown in FIG. 1, is connected to the upper part of the motor housing 21 and extends in the front-rear direction. The gear housing 22 houses a power transmission unit 5 and a part of the output unit 6 inside the gear housing 22. A vibration reducing mechanism 22A is provided at the rear portion of the upper part of the gear housing 22. The vibration reduction mechanism 22A has a plurality of elastic bodies 22B formed in a substantially cylindrical shape extending in the vertical direction. The vibration reduction mechanism 22A is an example of the "vibration reduction unit" in the present invention.

The power transmission unit 5 has a pinion gear 51 fixed to the upper end of the rotating shaft 41 of the motor 4 and a power conversion mechanism 52. The power transmission unit 5 is an example of the "power transmission unit" in the present invention.

The power conversion mechanism 52 is a mechanism that converts the rotational force of the motor 4 into a reciprocating motion in the front-rear direction and transmits it to the output unit 6. The crankshaft 52A, the gear 52B, the crank weight 52C, the crank pin 52D, and the connecting rod. It has a rod 52E.

The crankshaft 52A extends in the vertical direction and is arranged behind the pinion gear 51, and is rotatably supported by the gear housing 22. The gear 52B is coaxially fixed to the crankshaft 52A and meshes with the pinion gear 51. The crank weight 52C is fixed to the upper end of the crankshaft 52A. The crank pin 52D extends in the vertical direction and is provided on the upper surface of the crank weight 52C at a position eccentric with respect to the rotation axis of the crankshaft 52A. The connecting rod 52E extends in the front-rear direction, a crank pin 52D is inserted into the rear end portion thereof, and the front end portion thereof is connected to the output unit 6.

The output unit 6 includes a cylinder 61, a piston 62, a striking element 63, a meson 64, and a tool holding unit 65. The output unit 6 is an example of the “output shaft unit” in the present invention.

The cylinder 61 has a substantially cylindrical shape extending in the front-rear direction. The piston 62, the striking element 63, and the meson 64 are arranged inside the cylinder 61 in this order from the rear, and are configured to be slidable in the front-rear direction with respect to the inner peripheral surface of the cylinder 61. The piston 62 is connected to the front end of the connecting rod 52E, and an air chamber 6a is defined between the piston 62 and the striking element 63. The tool holding portion 65 is located in front of the cylinder 61 and is configured so that the tip tool P can be attached and detached.

The handle housing 3 is located behind the main body housing 2. As shown in FIG. 2, the handle housing 3 integrally includes a grip portion 31, an upper connecting portion 32, a lower connecting portion 33, and a rotation allowing portion 34. The handle housing 3 is configured as a divided housing divided by a divided surface (cross section along the I-I line shown in FIG. 2) that passes substantially in the center in the left-right direction and is orthogonal to the left-right direction. It is composed of a right handle housing 3A (FIG. 2) which is a portion and a left handle housing 3B (FIG. 2) which is a left portion. The handle housing 3 is connected to the main body housing 2 by butt-joining the right handle housing 3A and the left handle housing 3B with each other at a split surface. Further, as shown in FIG. 1, a power cord 3C connected to an external power source (not shown) extends from the lower part of the handle housing 3. The handle housing is an example of a "handle" in the present invention. The right handle housing 3A is an example of the "half-split first portion" in the present invention, and the left handle housing 3B is an example of the "half-split second portion" in the present invention.

The grip portion 31 is a portion gripped by an operator during work and has a substantially cylindrical shape extending in the vertical direction. A trigger 35 that can be pulled by an operator is provided on the upper portion of the grip portion 31. In the present embodiment, power is supplied to the motor 4 from an external power source (not shown) via the power strip 3C by performing a pulling operation on the trigger 35.

The upper connecting portion 32 extends forward from the upper end portion of the grip portion 31 and has a substantially cylindrical shape that opens forward. A part of the vibration reducing mechanism 22A is housed inside the upper connecting portion 32. In other words, the upper connecting portion 32 is connected to the gear housing 22 via the vibration reducing mechanism 22A.

The lower connecting portion 33 extends forward from the lower end portion of the grip portion 31 and has a substantially cylindrical shape that opens forward. A rotation permitting portion 34 is provided at the front portion of the lower connecting portion 33. The details of the rotation permitting portion 34 will be described later. A part of the lower connection portion 33 in the drawing is shown by hatching from the upper left to the lower right.

Next, the rotation unit 23 and the rotation allowance unit 34 will be described in detail with reference to FIGS. 2 and 3.

As shown in FIG. 1, the rotating portion 23 extends rearward from the rear portion of the connecting portion 21A, and as shown in FIG. 2, the first cylindrical portion 23A, the connecting portion 23B, and the first It has two cylindrical portions 23C.

The first cylindrical portion 23A has a substantially cylindrical shape extending in the left-right direction.

The second cylindrical portion 23C has a substantially cylindrical shape extending in the left-right direction. The diameter of the second cylindrical portion 23C is larger than the diameter of the first cylindrical portion 23A. The inner peripheral surface on the right side of the second cylindrical portion 23C defines the first sliding surface 23D, and the inner peripheral surface on the left side defines the second sliding surface 23E. The inner peripheral surface of the second cylindrical portion 23C defines an accommodating space for accommodating the blocking portion 341 of the rotation permitting portion 34, which will be described later.

The connecting portion 23B has a substantially annular shape extending radially outward from the first cylindrical portion 23A from the outer peripheral surface of the first cylindrical portion 23A, and is connected to the inner peripheral surface of the second cylindrical portion 23C. The first cylindrical portion 23A, the second cylindrical portion 23C, and the connecting portion 23B are integrally formed and are configured substantially symmetrically with respect to the cross section along the I-I line shown in FIG.

The rotation permitting portion 34 is located at the front portion of the lower connecting portion 33 of the handle housing 3 as shown in FIG. 1, and has a stepped shape as shown in FIG. .. The rotation allowing portion 34 is rotatably connected to the main body housing 2 in a state of accommodating the rotating portion 23 forming a part of the main body housing 2. The rotation allowance portion 34 includes a blocking portion 341, a right side regulation portion 342, a left side regulation portion 343, a right side slide allowance portion 344, a left side slide allowance portion 345, a first right side connection portion 346, a first left side connection portion 347, and a first. 2 It has a right side connection part 348, a second left side connection part 349, a third right side connection part 350, and a third left side connection part 351. Further, the rotation allowing portion 34 is integrally provided with the handle housing 3. This makes it possible to reduce the number of parts. In the present embodiment, the rotation permitting portion 34 has substantially the same configuration as that shown in FIG. 2 in any cross section (for example, II-II cross section) including the axis A of the blocking portion 341. Have.

As shown in FIG. 2, the blocking portion 341 is located inside the first cylindrical portion 23A of the rotating portion 23 in the radial direction, and includes the first base portion 341A, the protruding portion 341B, and the second base portion 341C. It has a tubular portion 341D. The blocking unit 341 is an example of the "blocking unit" in the present invention.

The first base portion 341A forms a part of the right handle housing 3A and the right portion of the blocking portion 341, and is formed in a substantially cylindrical shape extending in the left-right direction. A through hole is formed at substantially the center of the first base portion 341A in the radial direction to penetrate the first base portion 341A in the left-right direction.

The protruding portion 341B has a substantially cylindrical shape extending to the left from the first base portion 341A. The first base portion 341A and the protruding portion 341B are integrally formed.

The second base portion 341C forms a part of the left handle housing 3B and the left portion of the blocking portion 341, and is provided at a position substantially symmetrical with the first base portion 341A with respect to the cross section along the I-I line.

The tubular portion 341D has a substantially cylindrical shape extending to the right from the second base portion 341C. The diameter of the outer circumference of the tubular portion 341D is slightly smaller than the diameter of the inner circumference of the protruding portion 341B. The right end surface of the tubular portion 341D abuts on the left end surface of the first base portion 341A, thereby preventing the right handle housing 3A and the left handle housing 3B from moving close to each other in the butt direction (left-right direction). .. The outer peripheral surface of the right portion of the tubular portion 341D faces the inner peripheral surface of the protruding portion 341B, whereby the right handle housing 3A and the left handle housing 3B are prevented from moving relative to each other in the radial direction of the tubular portion 341D. ing. Further, a hole extending in the left-right direction is formed at substantially the center of the tubular portion 341D in the radial direction. The hole of the tubular portion 341D and the through hole of the first base portion 341A communicate with each other to form a screw screw hole 34a. A screw 1A is screwed into the screw screw hole 34a, and the right handle housing 3A and the left handle housing 3B are fixed so as not to be relatively movable with each other. In the present embodiment, the screw 1A is a tapping screw.

The right side regulation part 342 and the left side regulation part 343 are configured substantially symmetrically with respect to the cross section along the I-I line. The right side regulating portion 342 and the left side regulating portion 343 are located radially outside the first base portion 341A and the second base portion 341C, respectively. The right side regulation unit 342 and the left side regulation unit 343 are examples of the "regulation unit" in the present invention.

The right side regulating portion 342 is in contact with the right end portion of the first cylindrical portion 23A of the rotating portion 23, and the left side regulating portion 343 is in contact with the left end portion of the first cylindrical portion 23A. That is, the right side regulating portion 342 and the left side regulating portion 343 sandwich the first cylindrical portion 23A, which is a part of the main body housing 2, in the abutting direction (left-right direction) of the right handle housing 3A and the left handle housing 3B, and in the left-right direction. The relative movement between the handle housing 3 and the main body housing 2 is restricted.

The right side slide allowance portion 344 and the left side slide allowance portion 345 are configured substantially symmetrically with respect to the cross section along the I-I line. The right side slide allowance portion 344 and the left side slide allowance portion 345 have a substantially cylindrical shape extending in the left-right direction. The right side sliding allowance 344 and the left side sliding allowance 345 are located radially outside the right side regulating part 342 and the left side regulating part 343, respectively. Further, the right side slide allowance portion 344 and the left side slide allowance portion 345 are formed in a cylindrical shape concentric with the blocking portion 341. The right sliding surface 344A is defined by the inner peripheral surface of the right sliding allowable portion 344, and the left sliding surface 345A is defined by the inner peripheral surface of the left sliding allowable portion 345. The right side slide allowance portion 344 and the left side slide allowance portion 345 are examples of the "guide portion" in the present invention. The right side sliding surface 344A and the left side sliding surface 345A are examples of the "sliding surface" in the present invention.

As shown in FIG. 3, the right sliding surface 344A is defined by the outer circumference of the right sliding allowable portion 344 over the entire circumference of the right sliding allowable portion 344 in the circumferential direction. Further, although not shown in the figure, the left sliding surface 345A is similarly defined by the outer circumference of the left sliding allowable portion 345 over the entire circumference in the circumferential direction of the left sliding allowable portion 345. As shown in FIG. 2, the right sliding surface 344A and the left sliding surface 345A are the first sliding surface 23D and the second sliding surface of the second cylindrical portion 23C in the radial direction of the blocking portion 341, respectively. It faces 23E. The curvatures of the right sliding surface 344A, the left sliding surface 345A, the first sliding surface 23D, and the second sliding surface 23E are substantially the same. The right sliding surface 344A and the first sliding surface 23D slide, and the left sliding surface 345A and the second sliding surface 23E slide, so that the main body housing 2 and the handle housing 3 are blocked from each other. It is possible to rotate relative to the axis A of the portion.

Further, as shown in FIG. 3, the first sliding surface 23D and the right side sliding surface 344A are in contact with each other with respect to the second cylindrical portion 23C and the right side sliding allowable portion 344, which are formed in a cylindrical shape, respectively. The handle of the main body housing 2 is caused by the contact between the second sliding surface 23E and the left sliding surface 345A with respect to the second cylindrical portion and the left sliding allowable portion 345, which are not shown in the above but are formed in a cylindrical shape. The position of the blocking portion 341 with respect to the housing 3 in the radial direction is positioned. As a result, the main body housing 2 can be preferably rotated with respect to the handle housing 3.

As shown in FIG. 2, the first right side connection portion 346 and the first left side connection portion 347 are configured substantially symmetrically with respect to the cross section along the I-I line of FIG. The first right side connection part 346 connects the first base part 341A and the right side regulation part 342, and the first left side connection part 347 connects the second base part 341C and the left side regulation part 343. The first right side connecting portion 346 is curved with a predetermined curvature so as to extend outward in the radial direction of the blocking portion 341 at the right portion of the blocking portion 341. Further, the first left side connecting portion 347 is curved with a predetermined curvature so as to extend outward in the radial direction of the blocking portion 341 at the left portion of the blocking portion 341. That is, the first right side connection portion 346 and the first left side connection portion 347 are configured with a predetermined curvature. According to such a configuration, it is possible to disperse the stress that is preferably generated during work and acts on the connection portion, and it is possible to prevent the handle housing 3 from being damaged.

The second right side connecting portion 348 and the second left side connecting portion 349 are configured substantially symmetrically with respect to the cross section along the I-I line of FIG. The second right side connecting portion 348 connects the right side regulating portion 342 and the right side sliding allowable portion 344, and the second left side connecting portion 349 connects the left side regulating portion 343 and the left side sliding allowable portion 345. The second right side connecting portion 348 is curved with a predetermined curvature so as to extend outward in the radial direction of the right side regulating portion 342 and to the right. Further, the second left side connecting portion 349 is curved with a predetermined curvature so as to extend outward in the radial direction of the left side regulating portion 343 and to the left. That is, the second right side connecting portion 348 and the second left side connecting portion 349 are configured with a predetermined curvature. According to such a configuration, it is possible to disperse the stress that is preferably generated during work and acts on the connection portion, and it is possible to prevent the handle housing 3 from being damaged.

The third right side connection portion 350 and the third left side connection portion 351 are configured substantially symmetrically with respect to the cross section along the line I-I of FIG. The third right side connection portion 350 is located radially outside the right side slide allowance portion 344, and the third left side connection portion 351 is located outside the left side slide allowance portion 345 in the radial direction. The third right side connecting portion 350 is curved with a predetermined curvature so as to extend outward in the radial direction of the right side sliding allowable portion 344 while extending to the right. Further, the third left side connecting portion 351 is curved with a predetermined curvature so as to extend to the left and to extend outward in the radial direction of the left side sliding allowable portion 345. That is, the third right side connection portion 350 and the third left side connection portion 351 are configured to have a predetermined curvature. According to such a configuration, it is possible to disperse the stress that is preferably generated during work and acts on the connection portion, and it is possible to prevent the handle housing 3 from being damaged.

In the present embodiment, the right side regulating part 342 and the left side regulating part 343 are located between the right side sliding surface 344A and the left side sliding surface 345A and the blocking part 341 in the radial direction of the blocking part 341. Therefore, the first right side connection part 346, the first left side connection part 347, the second right side connection part 348, the second left side connection part 349, the third right side connection part 350, and each of them are preferably configured with a predetermined curvature. It is possible to provide the third left side connection portion 351.

Next, the operation of the hammer 1 will be described with reference to FIGS. 1 to 3.

The operator presses the tip tool P mounted on the tool holding portion 65 against the work material while gripping the grip portion 31. When the operator operates the trigger 35 in this state, electric power is supplied to the motor 4 from an external power source (not shown) via the power strip 3C, and the rotating shaft 41 rotates. The rotational force of the rotating shaft 41 is transmitted to the crankshaft 52A via the pinion gear 51 and the gear 52B. The rotational force of the crankshaft 52A is converted into a reciprocating motion of the piston 62 inside the cylinder 61 in the front-rear direction by the crank weight 52C, the crank pin 52D, and the connecting rod 52E.

Due to the reciprocating movement of the piston 62, the pressure of the air inside the air chamber 6a repeatedly rises and falls, and the striking force is repeatedly applied to the striking element 63, so that the striking element 63 reciprocates in the front-rear direction. As a result, the action of the striking element 63 striking the rear end of the meson 64 is repeated, and the striking force is periodically and repeatedly transmitted to the tip tool P via the meson 64. The material to be worked is crushed by the striking force periodically applied to the tip tool P.

During the crushing operation using the hammer 1 described above, vibration in the front-rear direction is mainly generated in the main body housing 2 due to the reciprocating movement of the piston 62, the hammer 63 and the meson 64 in the front-rear direction. In this case, in the present embodiment, the right side sliding surface 344A and the first sliding surface 23D slide, and the left side sliding surface 345A and the second sliding surface 23E slide. , The main body housing 2 and the handle housing 3 rotate relative to each other about the axis A of the blocking portion 341. Then, the elastic body 22B of the vibration reduction mechanism 22A is expanded and contracted by the relative rotation of the handle housing 3 and the main body housing 2, so that the vibration in the axial direction of the tip tool P is absorbed, and the grip portion 31 is gripped. It is reduced that the vibration of the tip tool P in the axial direction is transmitted to the person.

Here, conventionally, when the handle and the main body rotate relative to each other around a single shaft provided on the handle, an excessive load is applied to the shaft, and the handle may be damaged. There was sex.

However, in the present embodiment, as shown in FIG. 2, the rotation allowance portion 34 is configured in a stepped shape, and the right handle housing 3A and the left handle housing 3B of the handle housing 3 are in the butt direction. Right side sliding allowance 344 having a right side sliding surface 344A and a left side sliding surface 345A that guide the relative rotation between the handle housing 3 and the main body housing 2 on the radial outer side of the blocking part 341 that prevents them from moving close to each other. And the left side sliding allowance 345 is provided. Therefore, the load applied to the blocking unit 341 is reduced as compared with the case where the load due to rotation is directly applied to the blocking unit 341. That is, the blocking portion 341 is mainly subjected to a load in the left-right direction that prevents the right handle housing 3A and the left handle housing 3B from moving in close proximity, and the load due to the relative rotation between the handle housing 3 and the main body housing 2 is mainly on the right side. Since it is applied to the sliding allowable portion 344 and the left sliding allowable portion 345, the load is suitably distributed and it is possible to prevent the handle from being damaged. The curvatures of the first right side connection part 346, the first left side connection part 347, the second right side connection part 348, the second left side connection part 349, the third right side connection part 350, and the third left side connection part 351 are all. The shape may have a curvature, and it is desirable that the curvature is small.

Next, the hammer 100, which is an example of the power tool according to the second embodiment of the present invention, will be described with reference to FIGS. 4 to 7. The hammer 100 basically has the same configuration as the hammer 1 according to the second embodiment, and the description of the same configuration as that of the hammer 1 is omitted as appropriate, and mainly different configurations are omitted. explain.

As shown in FIG. 4, in the hammer 100 according to the second embodiment, the rotation portion 123 is provided in place of the rotation portion 23, and the rotation allowance portion 34 is replaced with the rotation allowance portion 34. 134 is provided.

As shown in FIG. 5, the structure of the rotating portion 123 and the rotating allowing portion 134 with respect to the cross section along the VV line of FIG. 4 is such that the hammer 100 according to the second embodiment is the first. It has the same effect as the hammer 1 according to the embodiment. In the present embodiment, the rotation portion 123 and the rotation allowance portion 134 have any cross section (for example, VV cross section) including the axis A of the blocking portion 1341 and intersecting the right sliding surface 1344A. It has substantially the same configuration as the configuration shown in 5.

The rotating portion 123 has a contact portion 123I as shown in FIG. 6 and a recess 123G as shown in FIG. 7. Further, as shown in FIG. 7, the second cylindrical portion 123C is formed in a cylindrical shape in which the second cylindrical portion 23C extends in the left-right direction in the first embodiment, and is formed in the front-rear direction. It is configured as a pair of opposing arcs. Although not shown in the figure, the first cylindrical portion 123A is also configured as a pair of arc portions facing each other in the front-rear direction. The first sliding surface 123D and the second sliding surface 123E face each other in the front-rear direction (see FIG. 7). The first sliding surface 123D and the second sliding surface 123E are examples of the "pair of arcuate surfaces" in the present invention.

As shown in FIG. 7, the contact portion 123I is formed in a substantially flat plate shape extending in the front-rear direction, and is configured as a pair of flat plate portions facing each other in the vertical direction. The respective anteroposterior ends of the abutting portions 123I facing each other are connected to the respective vertical ends of the arcuate second cylindrical portions 123C facing each other. The inner peripheral surfaces of the abutting portion 123I and the second cylindrical portion 123C define an accommodating space for accommodating the blocking portion 1341 of the rotation permitting portion 134. Further, a pair of contact surfaces 123F facing each other in the vertical direction are defined by the inner peripheral surfaces of the contact portion 123I. The pair of contact surfaces 123F is an example of a "pair of planes" in the present invention.

The recess 123G is located at a position rotationally symmetrical with respect to the axis A of the blocking portion 1341. The recess 123G is recessed outward in the radial direction of the blocking portion 1341, and the concave surface 123H is defined by the inner peripheral surface of the recess 123G. The recess 123G is an example of the "connection portion" in the present invention.

As shown in FIG. 5, the right side sliding allowed portion 1344 has a right arc portion 1358, and the left side sliding allowed portion 1345 has a left arc portion 1359. As shown in FIG. 7, the right arc portion 1358 forms a pair of arcs facing each other in the front-rear direction in the cross section along the VII-VII line of FIG. Although not shown in the figure, the left arc portion 1359 also has an arc shape facing in the front-rear direction. The right side slide allowance portion 1344 and the left side slide allowance portion 1345 are examples of the "guide portion" in the present invention. The right arc portion 1358 and the left arc portion 1359 are examples of the “arc portion” in the present invention.

As shown in FIG. 5, the right side sliding surface 1358A and the left side sliding surface 1359A are defined by the outer peripheral surfaces of the right arc portion 1358 and the left arc portion 1359, respectively. Each of the right side sliding surface 1358A and the left side sliding surface 1359A faces the first sliding surface 123D and the second sliding surface 123E of the second cylindrical portion 123C in the radial direction of the blocking portion 1341. The curvatures of the right sliding surface 1358A, the left sliding surface 1359A, the first sliding surface 123D, and the second sliding surface 123E are substantially the same.

Further, as shown in FIG. 6, the right side sliding allowable portion 1344 has a right side flat plate portion 1352, and the left side sliding allowable portion 1345 has a left side flat plate portion 1353. The right flat plate portion 1352 and the left flat plate portion 1353 are examples of the "straight line portion" in the present invention.

The right flat plate portion 1352 and the left flat plate portion 1353 are configured substantially symmetrically with respect to the cross section along the IV-IV line. The right flat plate portion 1352 and the left flat plate portion 1353 are located radially outside the first base portion 1341A and the second base portion 1341C of the blocking portion 1341, respectively. The right flat plate portion 1352 and the left flat plate portion 1353 have a flat plate shape extending in the front-rear direction. Further, as shown in FIG. 7, the cross-sectional shape of the right flat plate portion 1352 in the virtual plane orthogonal to the axis A of the blocking portion 1341 (cross-sectional shape along the VII-VII line of FIG. 6) is in the vertical direction. It is configured as a pair of straight sections facing each other. In the cross section, the right flat plate portion 1352 and the right arc portion 1358 form a quadrangular shape of the right sliding allowable portion 1344.

As shown in FIG. 6, the right side contact surface 1352A and the left side contact surface 1353A are defined by the outer peripheral surfaces of the right side plate portion 1352 and the left side plate portion 1353, respectively. Each of the right side contact surface 1352A and the left side contact surface 1353A faces the contact portion 123I and the recess 123G in the vertical direction (see FIG. 7).

As shown in FIG. 7, since the recess 123G is recessed outward in the radial direction of the blocking portion 1341, the handle housing 3 and the main body housing 2 rotate relative to each other about the axis A of the blocking portion 1341. It is possible. Further, when vibration is generated in the main body housing 2, when the main body housing 2 rotates in the counterclockwise direction of FIG. 7 about the axis A with respect to the handle housing 3, after a predetermined amount of rotation, the right side The contact surface 1352A and the left side contact surface 1353A come into contact with the concave surface 123H. When the main body housing 2 rotates in the clockwise direction of FIG. 7 with respect to the handle housing 3 about the axis A, the right side contact surface 1352A and the left side contact surface 1353A become contact surfaces after a predetermined amount of rotation. It comes into contact with 123F. As a result, the main body housing 2 does not rotate more than necessary with respect to the handle housing 3, it is not necessary to provide another member for restricting the rotation, and the number of parts can be reduced.

Further, as shown in FIG. 6, the rotation allowance unit 134 has a fourth right side connection part 1354, a fourth left side connection part 1355, a fifth right side connection part 1356, and a fifth left side connection part 1357. There is.

The fourth right side connection portion 1354 and the fourth left side connection portion 1355 are configured substantially symmetrically with respect to the cross section along the IV-IV line of FIG. The fourth right side connecting portion 1354 connects the first base portion 1341A and the right side flat plate portion 1352, and the fourth left side connecting portion 1355 connects the second base portion 1341C and the left side flat plate portion 1353. The fourth right side connecting portion 1354 is curved with a predetermined curvature so as to extend outward in the radial direction of the blocking portion 1341 at the right portion of the blocking portion 1341. Further, the fourth left side connecting portion 1355 is curved with a predetermined curvature so as to extend outward in the radial direction of the blocking portion 1341 at the left portion of the blocking portion 1341. That is, the 4th right side connection portion 1354 and the 4th left side connection portion 1355 are configured with a predetermined curvature. According to such a configuration, it is possible to disperse the stress that is preferably generated during work and acts on the connection portion, and it is possible to prevent the handle housing 3 from being damaged.

The fifth right side connection portion 1356 and the fifth left side connection portion 1357 are configured substantially symmetrically with respect to the cross section along the IV-IV line of FIG. The fifth right side connection portion 1356 is located radially outside the right side plate portion 1352, and the fifth left side connection portion 1357 is located radially outside the left side plate portion 1353. The fifth right side connecting portion 1356 is curved with a predetermined curvature so as to extend to the right and to extend outward in the radial direction of the right flat plate portion 1352. Further, the fifth left side connecting portion 1357 is curved with a predetermined curvature so as to extend to the left and to extend outward in the radial direction of the left side flat plate portion 1353. That is, the fifth right side connection portion 1356 and the fifth left side connection portion 1357 are configured with a predetermined curvature. According to such a configuration, the stress generated at the time of work and generated at the connection portion can be dispersed, and the handle housing 3 can be prevented from being damaged. The curvatures of the 4th right side connection part 1354, the 4th left side connection part 1355, the 5th right side connection part 1356, and the 5th left side connection part 1357 may all have a curved shape, and the curvature is small. Is preferable.

In this specification, hammers 1 and 100 have been described as an example, but the present invention can also be applied to a power tool driven by a motor other than the hammer, and in particular, the axial direction of the output shaft portion such as a saver saw and a vibration drill. It is particularly suitable for electric tools that perform work by reciprocating the tip tool.

1 ... Hammer 2 ... Main body housing 3 ... Handle housing 4 ... Motor 5 ... Power transmission unit 6 ... Output unit

Claims (8)

Body housing and
It has a handle that is connected to the main body housing by butt-joining the first portion and the second portion of the half-split shape.
Said first portion and a second portion, before SL has a rotation allowing portion that is pivotally connected to the body housing,
The rotation permitting portion is located at a columnar blocking portion that prevents the first portion and the second portion from coming into close contact with each other in the abutting direction and radially outside the blocking portion. It also has a guide portion having a handle-side sliding surface that guides the rotation of the handle with respect to the main body housing about the axis of the blocking portion.
The main body housing has a main body side sliding surface that slides with respect to the handle side sliding surface.
The position of the main body housing with respect to the handle in the radial direction of the blocking portion is positioned by abutting the main body side sliding surface with the handle side sliding surface .
A power tool characterized in that the distance between the blocking portion and the main body housing is larger than the distance between the handle-side sliding surface and the main body-side sliding surface. The rotation permitting portion further has a regulating portion located between the handle-side sliding surface and the blocking portion in the radial direction of the blocking portion, and the regulating portion further comprises a part of the main body housing. The power tool according to claim 1, wherein the power tool is sandwiched in the butt direction to regulate the relative movement of the handle and the main body housing in the axial direction of the rotation. The handle further has a handle body portion connected to the guide portion.
The blocking unit and the regulating unit are connected to each other.
The regulation unit and the guide unit are connected to each other.
The connection portion between the blocking portion and the regulation portion, the connection portion between the regulation portion and the guide portion, and the connection portion between the guide portion and the handle main body portion are each configured with a predetermined curvature. The power tool according to claim 2. The guide portion is formed in a cylindrical shape concentric with the blocking portion.
The power tool according to any one of claims 1 to 3, wherein the handle-side sliding surface is defined by the outer circumference of the guide portion over the entire circumference in the circumferential direction of the guide portion. Body housing and
It has a handle that is connected to the main body housing by butt-joining the first portion and the second portion of the half-split shape.
The first portion and the second portion have a rotation allowance portion that is rotatably connected to the main body housing.
The rotation permitting portion is located at a columnar blocking portion that prevents the first portion and the second portion from coming into close contact with each other in the abutting direction and radially outside the blocking portion. It also has a guide portion having a sliding surface that guides the rotation of the handle with respect to the main body housing about the axis of the blocking portion.
The position of the main body housing with respect to the handle in the radial direction of the blocking portion is positioned by the sliding surface.
The guide portion has a cross-sectional shape in a virtual plane orthogonal to the axis of the blocking portion, and has a square shape composed of a pair of straight portions facing each other and a pair of arc portions facing each other. A space defined by a pair of arcuate surfaces that slide in front of the pair of arcuate portions and a pair of planes that face and abut against the pair of straight portions is provided, and the pair of arcuate surfaces and the pair. radius recessed in a direction outward, before Symbol handle and the moving tool electrostatic you characterized in that it permits relative rotation of the body housing the connecting portion of the plane of said blocking portion. The power tool according to any one of claims 1 to 5, wherein the rotation permitting portion is integrally provided on the first portion and the second portion of the handle. The motor supported by the main body housing and
Further having an output shaft portion supported by the main body housing and driven by the rotational force of the motor.
The handle further has a vibration reducing portion connected to the main body housing in a state in which axial vibration of the output shaft portion can be reduced, and the rotation allowing portion and the vibration reducing portion with respect to the main body housing. The power tool according to any one of claims 1 to 6, wherein the power tool is connected at two locations. The motor has a rotating shaft and
The output shaft portion is configured so that the tip tool can be attached and detached.
The power tool according to claim 7, further comprising a power transmission unit capable of converting the rotary motion of the rotary shaft into a reciprocating motion and reciprocating the tip tool in the axial direction.

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