JP5668525B2 - Electric tool - Google Patents

Description

  The present invention relates to an electric tool that drives a tip tool with an electric motor, and more particularly to an electric tool that can switch an operation mode by rotating a switching member attached to a case.

  For example, a hammer drill is known as an electric tool in which a tip tool is driven by an electric motor built in the case. A hammer drill is used for drilling a work material such as concrete or brick, and a drill bit or the like is used as a tip tool thereof.

  Such hammer drills are equipped with a power conversion mechanism that selectively converts the output of the electric motor into a plurality of types of motion and transmits it to the tip tool, such as a switching dial or a switching lever that is rotatably attached to the case. By rotating the switching member, the operation mode of the tip tool can be switched to a plurality of modes according to the work situation.

  For example, in the hammer drill shown in Patent Document 1, the operation mode is changed to a rotation mode for rotating the tip tool, a rotation hit mode for rotating the tip tool and applying a hitting force thereto, and hitting the tip tool. It is possible to switch to three modes, a batting mode that applies only force.

JP 2010-173053 A

  In the conventional hammer drill, the switching member is attached to the case by inserting the mounting boss portion provided in the shaft center of the switching member into the mounting hole provided in the case, and the tip of the mounting boss portion protruding inside the case. This is done by fixing a retaining ring (C ring).

  However, in the structure where the switching member is attached to the case by fixing the retaining ring to the tip of the mounting boss, it is necessary to attach a small retaining ring to the tip of the mounting boss within the narrow case. The operation of attaching the member to the case was complicated.

  An object of the present invention is to facilitate an operation of attaching a switching member to a case.

An electric tool of the present invention is an electric tool that drives a tip tool by an electric motor, and a case that accommodates the electric motor, and an electric motor that is accommodated in the case and selectively outputs a plurality of types of movement of the electric motor. A power conversion mechanism that converts and transmits the power to the tip tool, a switching member that is rotatably mounted on the case and is operated to rotate, thereby switching a power conversion mode of the power conversion mechanism, and toward the case A lock release button provided on the switching member in a state of being provided with a projecting control pin and being urged radially outward, and provided on the case, is engaged with the control pin to control the operation of the switching member. A control groove, and the switching member is detachable with respect to the mounting hole of the case when it is in the attaching / detaching position, and is locked to the case by rotating from the attaching / detaching position. Includes a mounting boss that, the switching member by engaging to the case of the mounting boss portion is mounted on said casing, said control groove about the axis of the mounting hole and the circular arc-shaped connection groove A plurality of lock grooves that are connected to the connection groove toward the radially outer side, and that engage with the control pin when the switching member is in a position corresponding to each mode, respectively, and a circumference with respect to the connection groove An attachment / detachment groove that is shifted in a direction and that is connected to the connection groove via a guide groove that is radially inward of the connection groove and engages the control pin when the switching member is in the attachment / detachment position. Drop-off prevention means for preventing the switch member from dropping from the case by preventing the control pin from moving from the connecting groove to the detachable groove when the switch member is rotated. Characterized by having That.

  The electric power tool according to the present invention is characterized in that the power conversion mechanism is a three-mode type in which the output of the electric motor is converted into a rotational motion, a rotational impact motion or an impact motion and transmitted to the tip tool.

  In the electric power tool of the present invention, the drop-off prevention means is a locking projection that is provided adjacent to a communication portion of the guide groove with the connection groove and protrudes radially outward from a radially inner side surface of the connection groove. It is characterized by being.

  The electric power tool of the present invention is characterized in that the drop-off prevention means has a structure in which the guide groove is connected to the connection groove between the two lock grooves.

  The power tool of the present invention is characterized in that the drop-off prevention means has a structure in which the guide groove is bent in a crank shape between the connection groove and the attachment / detachment groove.

  According to the present invention, the switching member can be attached to the case by inserting the mounting boss portion into the mounting hole of the case in the state of being aligned with the attaching / detaching position and rotating the switching member while operating the lock release button. Therefore, a complicated operation such as fixing a retaining ring to the tip of the mounting boss portion inside the case is unnecessary, and the mounting operation of the switching member to the case can be facilitated. Also, the control groove that controls the operation of the switching member by engagement with the control pin is provided with a drop prevention means to prevent the control pin from moving from the connecting groove to the attaching / detaching groove. Even when the switching member is attached to the case by rotating from the attachment / detachment position, it is possible to prevent the switching member from being accidentally dropped from the case during the operation mode switching operation. As the power conversion mechanism, a three-mode type that converts the output of the electric motor into a rotational motion, a rotational striking motion, or a striking motion and transmits it to the tip tool can be used.

  According to the present invention, the drop-off preventing means is configured as a locking projection that is adjacent to the communicating portion of the guide groove with the connecting groove and protrudes radially outward from the radially inner side surface of the connecting groove. Even if the switching member is rotated while the release button is pressed, the control pin is brought into contact with the locking projection and is prevented from further movement, so that it does not unexpectedly enter the guide groove. Therefore, it is possible to prevent the switching member from being accidentally dropped from the case during the operation mode switching operation.

  According to the present invention, the drop-off preventing means has a structure in which the guide groove is connected to the connecting groove between the two lock grooves. Therefore, in order to rotate the switching member to the attachment / detachment position, the switching member is directed to the attachment / detachment position. After rotating to the stroke end, it is necessary to return to the opposite direction and then push the unlock button and rotate it again toward the attachment / detachment position. Therefore, it is possible to prevent the switching member from being accidentally dropped from the case during the operation mode switching operation.

  According to the present invention, the drop-off prevention means has a structure in which the guide groove is bent in a crank shape between the connection groove and the attachment / detachment groove, so that the control pin that enters the guide groove reaches the attachment / detachment groove to unlock. It is necessary to repeatedly perform the push-in / release operation of the button and the rotation operation of the switching member. Therefore, it is possible to prevent the switching member from being accidentally dropped from the case during the operation mode switching operation.

It is sectional drawing of the hammer drill which is one embodiment of this invention. It is an expanded sectional view which expands and shows the principal part of the rotary hammer drill shown in FIG. It is a perspective view of the switching dial shown in FIG. It is a front view which shows the detail of the mounting | wearing recessed part of the case shown in FIG. (A) is explanatory drawing which shows the state in which the switching dial was made into the attachment / detachment position, (b) is explanatory drawing which shows the state rotated to the position where the switching dial is mounted | worn to a case. It is sectional drawing which shows the detail of the attachment part to the case of a switching dial. It is explanatory drawing which shows a motion of the control pin when switching a switching dial to each mode selection position. (A)-(c) is explanatory drawing explaining the structure of the drop-off prevention means which prevents that a control pin moves to an attachment / detachment groove | channel unexpectedly, respectively. FIG. 3 is a modification of the control groove shown in FIG. 3, (a) is a front view showing a case where only a locking projection is provided, and (b) is a guide groove at a position shifted in the circumferential direction with respect to the lock groove The front view which shows the case where only the structure which continued to the connection groove | channel is provided, (c) is a front view which shows the case where only the guide groove bent in the crank shape is provided.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

  A hammer drill 11 as a power tool shown in FIG. 1 is a hand-held power tool used for drilling a work material such as concrete or brick.

  The hammer drill 11 includes a resin case 12. The case 12 is configured by combining a first case half body 12a integrally formed with a handle portion 13 and a cylindrical second case half body 12b with a bottom, and has a gun shape as a whole.

  An electric motor 14 serving as a drive source for the hammer drill 11 is accommodated in the case 12. In the illustrated case, a brushless motor is used as the electric motor 14. The electric motor 14 includes an output shaft 14a supported by two bearings 15 and 16, and the output shaft 14a is disposed in the axial direction of the second case half 12b.

  Reference numeral 17 denotes a fan fixed to the output shaft 14a.

  A control device 18 constituted by a microcomputer is accommodated in the handle portion 13 of the case 12, and the operation of the electric motor 14 is controlled by the control device 18. The control device 18 is connected to a commercial power source (not shown) via a power cord 19 drawn from the lower end of the handle portion 13. Further, a switch mechanism 21 is accommodated in the handle portion 13, and this switch mechanism 21 is also connected to the control device 18. The switch mechanism 21 has a trigger 22 protruding from the handle portion 13, and outputs a control signal corresponding to the operation amount (retraction amount) of the trigger 22 to the control device 18. That is, when the trigger 22 is operated by an operator or the like, the operation of the electric motor 14 is controlled by the control device 18 so as to have a speed corresponding to the operation amount of the trigger 22.

  A tool mounting portion 23 such as a socket or a chuck is rotatably provided at the distal end portion of the second case half 12b. A tip tool 24 such as a drill bit is attached to the tool mounting portion 23.

  Inside the case 12, a power conversion mechanism 31 is accommodated between the electric motor 14 and the tool mounting portion 23. The power conversion mechanism 31 is a three-mode type having three modes as its power conversion mode, and the output of the electric motor 14 is selectively selected from any one of rotational motion, rotational impact motion, and impact motion. It is converted and transmitted to the tip tool 24. That is, this hammer drill 11 can switch the operation mode to three modes of the rotation mode, the rotation hit mode, and the hit mode by switching the power conversion mode of the power conversion mechanism 31.

  Next, details of the power conversion mechanism 31 will be described.

  As shown in FIG. 2, the power conversion mechanism 31 includes an intermediate shaft 32 that is parallel to the output shaft 14 a of the electric motor 14. The intermediate shaft 32 is rotatably supported inside the case 12 by a bearing 33, and an input gear 34 is fixed to one end thereof. The input gear 34 is meshed with a first pinion 35 fixed to the tip of the output shaft 14 a of the electric motor 14. Thereby, when the electric motor 14 is operated, the intermediate shaft 32 is driven to rotate by the electric motor 14.

  A reciprocating bearing 36 is attached to the intermediate shaft 32 so as to be relatively rotatable. The reciprocating bearing 36 has an inner ring 36a, an outer ring 36b, and a rolling element 36c such as a ball disposed between them, and the outer ring 36b is provided with rotational movement of the inner ring 36a attached to the intermediate shaft 32. The output pin 36d is converted into a reciprocating motion.

  In order to intermittently transmit power between the intermediate shaft 32 and the reciprocating bearing 36, a clutch member 37 is attached to the intermediate shaft 32 adjacent to the reciprocating bearing 36 in the axial direction. The clutch member 37 is spline-engaged with the intermediate shaft 32, rotates with the intermediate shaft 32, and is movable in the axial direction with respect to the intermediate shaft 32. When the clutch member 37 moves to a position where it contacts the reciprocating bearing 36, clutch teeth (not shown) are engaged with each other, and the clutch member 37 engages with the inner ring 36a of the reciprocating bearing 36. As a result, the reciprocating bearing 36 is in a power transmission state in which the inner ring 36 a is fixed to the intermediate shaft 32 via the clutch member 37. On the other hand, when the clutch member 37 moves away from the reciprocating bearing 36 and the engagement of the clutch teeth (not shown) is released, the reciprocating bearing 36 enters a power cut-off state in which the rotation of the intermediate shaft 32 is not transmitted.

  Inside the case 12, a piston 38 is accommodated coaxially with the tool mounting portion 23 and parallel to the intermediate shaft 32, and an output pin 36 d of the reciprocating bearing 36 is connected to the piston 38. The piston 38 can reciprocate in the axial direction inside the case 12, and when the rotation of the intermediate shaft 32 is transmitted to the reciprocating bearing 36, it is driven by the output pin 36d to reciprocate in the axial direction. ing. A striking element 39 is accommodated in the piston 38 so as to be movable in the axial direction, and an intermediate element 41 is disposed between the tip tool 24 and the striking element 39. When the piston 38 reciprocates in the axial direction, pressure fluctuation occurs in the air chamber 42 formed by the striker 39 and the piston 38. When pressure fluctuation occurs in the air chamber 42, the striking element 39 is driven in the axial direction by the pressure fluctuation and collides with the intermediate element 41, and a striking force is applied to the tip tool 24 via the intermediate element 41. The striker 39 collides with the intermediate element 41 continuously in accordance with the reciprocation of the piston 38.

  Thus, when the rotation of the intermediate shaft 32 is transmitted to the reciprocating bearing 36, the output of the electric motor 14 is transmitted to the tip tool 24 as a striking motion.

  A pinion sleeve 43 is fixed to the tip of the intermediate shaft 32 by press fitting. Further, a second pinion 44 is attached to a portion of the intermediate shaft 32 between the clutch member 37 and the pinion sleeve 43 so as to be axially movable and relatively rotatable with respect to the intermediate shaft 32. The second pinion 44 moves to the side of the pinion sleeve 43, and the tip portion engages with the pinion sleeve 43, so that the second pinion 44 is in a power transmission state fixed to the intermediate shaft 32 via the pinion sleeve 43. In contrast, when the second pinion 44 moves away from the pinion sleeve 43 and is disengaged from the pinion sleeve 43, the second pinion 44 enters a power cut-off state in which the rotation of the intermediate shaft 32 is not transmitted.

  In order to transmit the rotation of the second pinion 44 to the tip tool 24, a cylinder 45 (rotation transmission sleeve) is accommodated in the case 12. The cylinder 45 is formed in a cylindrical shape, and accommodates the piston 38 therein so as to be relatively rotatable, and is connected to the tool mounting portion 23 at a tip portion thereof. An output gear 46 is fixed to the outer periphery of the cylinder 45, and this output gear 46 is engaged with the second pinion 44. Thus, when the rotation of the intermediate shaft 32 is transmitted to the second pinion 44 via the pinion sleeve 43, the rotation is transmitted to the cylinder 45, and the tool mounting portion 23, that is, the tip tool 24 rotates.

  A spring 47 is disposed between the clutch member 37 and the second pinion 44, and the clutch member 37 and the second pinion 44 are urged away from each other by the spring 47. Further, a switching sleeve 48 is mounted on the clutch member 37, and the clutch member 37 can be moved in a direction away from the reciprocating bearing 36 by driving the switching sleeve 48 in a direction away from the reciprocating bearing 36. ing.

  Next, a switching member for switching the power conversion mode of the power conversion mechanism 31 will be described.

  A switching dial 51 as a switching member is rotatably mounted on the lower surface of the second case half 12b. By rotating the switching dial 51, the power conversion mode of the power conversion mechanism 31 can be switched, and the operation mode of the hammer drill 11 can be set to any one of the rotation mode, the rotation impact mode, and the impact mode.

  The switching dial 51 is made of resin, and as shown in FIG. 3, has a substantially rectangular parallelepiped tunnel-shaped knob portion 51 b on one surface of a base 51 a formed in a disc shape.

  A mounting boss 51c is integrally provided on the other surface side of the base 51a. The mounting boss portion 51c is formed in a cylindrical shape coaxial with the base 51a, and four locking pieces 51d and 51e protruding radially outward are arranged at equal intervals in the circumferential direction on the outer peripheral portion thereof. . The three locking pieces 51d are set to have the same circumferential width, and the remaining one locking piece 51e is set to have a larger circumferential width than the other locking pieces 51d.

  On the other hand, a mounting recess 52 for mounting the switching dial 51 is provided on the lower surface of the second case half 12 b of the case 12. The mounting recess 52 is formed to be recessed in a circular shape, and as shown in FIG. The mounting hole 53 is formed in a shape including four cutout portions 53a and 53b corresponding to the locking pieces 51d and 51e of the mounting boss portion 51c on the outer peripheral edge of the circular hole portion. As with the locking pieces 51d and 51e, these notches 53a and 53b have the same width in the circumferential direction of the three notches 53a, and only the remaining one notch 53b has its circumference. The width in the direction is set larger than that of the other notch 53a. Each notch 53a, 53b is formed with a slightly larger circumferential width than the corresponding locking piece 51d, 51e, and each locking piece 51d, 51e has a corresponding notch 53a, 53b. It is possible to pass.

  As shown in FIG. 5 (a), the mounting boss 51c aligns the large locking piece 51e with the wide notch 53b and the other locking piece 51d with the small notch 53a. It is possible to attach / detach to / from the attachment hole 53 by adjusting the position to the position, that is, the attachment / detachment position. That is, the switching dial 51 is detachable from the case 12 when it is aligned with the attachment / detachment position.

  On the other hand, the attachment boss 51c is inserted into the attachment hole 53, and then the switching dial 51 is turned in the circumferential direction (counterclockwise direction in FIG. 5) from the attachment / detachment position, as shown in FIG. 5 (b). Each locking piece 51d, 51e is locked to the case 12, and the switching dial 51 is attached to the case 12 so as to be rotatable.

  As described above, in the hammer drill 11 according to the present invention, the switching boss 51c is inserted into the mounting hole 53 of the case 12 in a state where the switching dial 51 is aligned with the attaching / detaching position, and the switching dial 51 is rotated from this state to switch the switching dial 51. The dial 51 can be attached to the case 12. Therefore, complicated work such as attaching a retaining ring inside the case 12 becomes unnecessary, and the attaching work of the switching dial 51 to the case 12 is easy.

  A protrusion 51 f for switching the power conversion mode of the power conversion mechanism 31 is provided at the tip of the mounting boss 51 c of the switching dial 51. The protrusion 51f is formed integrally with the mounting boss 51c, and the shape thereof is cylindrical, and protrudes in the axial direction from the tip of the mounting boss 51c. Further, the protrusion 51f is arranged so as to be shifted (eccentric) from the axis of the switching dial 51 (mounting boss portion 51c). When the switching dial 51 is rotated, the projection 51f corresponds to the rotation of the power conversion mechanism 31. The axial position is displaced.

  As shown in FIG. 2, the protrusion 51 f is disposed between a switching sleeve 48 attached to the clutch member 37 and a flange 44 a provided on the second pinion 44. When the switching dial 51 is rotated, the protrusion 51f drives the switching sleeve 48 or the second pinion 44 in the axial direction according to the rotation direction thereof, and the power interruption between the intermediate shaft 32 and the reciprocating bearing 36, The power transmission between the intermediate shaft 32 and the second pinion 44 is interrupted.

  Next, the operation of switching the operation mode of the hammer drill 11 by rotating the switching dial 51 will be described.

  When the switching dial 51 is rotated and set to the position for selecting the rotation mode, that is, the rotation mode selection position, the projection 51f of the switching dial 51 is displaced to the right in the drawing with respect to the position shown in FIG. 48 is driven toward the right side in FIG. 2 by the protrusion 51f. When the switching sleeve 48 is driven toward the right side in FIG. 2, the clutch member 37 is moved away from the reciprocating bearing 36 by being pulled by the switching sleeve 48, and the engagement between the clutch member 37 and the reciprocating bearing 36 is released. Is done. At this time, the second pinion 44 is biased by the spring 47 and held in a state of being engaged with the pinion sleeve 43. Therefore, when the switching dial 51 is set to the rotation mode selection position, the output of the electric motor 14 is transmitted only to the tip tool 24 as a rotary motion, and the tip tool 24 is driven by the electric motor 14 to rotate.

  Next, when the switching dial 51 is operated to rotate and is set to the position for selecting the rotation impact mode (the position shown in FIG. 2), that is, the rotation impact mode selection position, the protrusion 51f of the switching dial 51 is shown in FIG. Displace to position. When the protrusion 51f is in the position shown in FIG. 2, the clutch member 37 is engaged with the reciprocating bearing 36, and the second pinion 44 is engaged with the pinion sleeve 43. Therefore, when the switching dial 51 is set to the rotational impact mode selection position, the output of the electric motor 14 is transmitted to the tip tool 24 as a rotational motion and also as an impact motion. That is, in the rotary impact mode, the tip tool 24 is driven by the electric motor 14 to rotate, and an impact force is applied thereto.

  Next, when the switching dial 51 is rotated and set to the position for selecting the batting mode, that is, the batting mode selection position, the projection 51f of the switching dial 51 is displaced to the left in the drawing with respect to the position shown in FIG. . When the protrusion 51f is displaced to the left in the drawing with respect to the position shown in FIG. 2, the flange 44a is pushed by the protrusion 51f and the second pinion 44 moves away from the pinion sleeve 43, and the pinion sleeve of the second pinion 44 is moved. The engagement with 43 is released. At this time, the clutch member 37 is biased by the spring 47 and is held in a state of being engaged with the reciprocating bearing 36. Therefore, when the switching dial 51 is set to the hitting mode selection position, the output of the electric motor 14 is transmitted only to the tip tool 24 as a hitting motion, and the tip tool 24 is actuated by applying only the hitting force without rotating. .

  Thus, by rotating the switching dial 51, the operation mode of the hammer drill 11 can be selectively switched to one of the rotation mode, the rotation hit mode, and the hit mode.

  In order to improve the operability of the switching dial 51, a function for fixing the rotationally operated switching dial 51 to each mode selection position is necessary. Further, as described above, the switching dial 51 becomes detachable with respect to the case 12 at the attachment / detachment position. Therefore, in order to prevent the switching dial 51 from falling off the case 12, the switching dial 51 is unexpectedly attached / detached. A structure that prevents movement to a position is required.

  Therefore, in the hammer drill 11 of the present invention, the switch dial 51 is provided with the lock release button 61 and the control pin 62 fixed to the lock release button 61 is engaged with the control groove 63 provided in the mounting recess 52 of the case 12. The operation of the switching dial 51 is controlled.

  As shown in FIG. 6, the lock release button 61 is attached to the knob portion 51 b of the switching dial 51. A spring 64 is accommodated inside the knob 51b, and the lock release button 61 is urged by the spring 64 in a direction protruding from the knob 51b (outside in the radial direction).

  The control pin 62 is made of a steel material having a circular cross section, and is fixed to the lower surface of the distal end portion of the lock release button 61 and protrudes from the lower surface toward the case 12.

  The control groove 63 is formed in the bottom surface portion around the mounting hole 53 of the mounting recess 52 of the case 12, and the cross section is rectangular in cross section, and the groove width is set wider than the outer diameter of the control pin 62. ing.

  When the switching dial 51 is attached to the case 12, the tip end portion of the control pin 62 engages with the control groove 63. The control pin 62 engaged with the control groove 63 can move only along the control groove 63. Thereby, the operation of the switching dial 51 in the rotation direction is controlled by these engagements so that the control pin 62 is moved along the control groove 63.

  The control groove 63 includes an arcuate connection groove 63 a centering on the attachment hole 53. In addition, lock grooves 63b, 63c, and 63d that protrude outward in the radial direction are provided continuously at both ends and an intermediate portion of the connection groove 63a. That is, the lock grooves 63b, 63c, and 63d are connected to each other by the connection groove 63a.

  As shown in FIG. 7, by moving the control pin 62 along the connecting groove 63a and engaging the control pin 62 with any of the lock grooves 63b, 63c, 63d, the switching dial 51 is moved to the rotation mode selection position, It can be held at the rotary impact mode selection position or the impact mode selection position. That is, when the control pin 62 is engaged with the lock groove 63b on the right side in FIG. 7, the switching dial 51 is in the rotation mode selection position, and when the control pin 62 is engaged with the central lock groove 63c, the switching dial 51 is rotated and hit. When the control pin 62 is engaged with the lock groove 63d on the left side in FIG. 7 when the mode selection position is reached, the switching dial 51 becomes the hitting mode selection position. Since the control pin 62 is urged radially outward by the spring 64 together with the lock release button 61, when the control pin 62 is engaged with any one of the lock grooves 63b, 63c, 63d, the switching dial 51 is held in that position. Is done. When the switching dial 51 is rotated to select another operation mode, the lock release button 61 is pressed to move the control pin 62 from the lock grooves 63b, 63c, 63d to the connection groove 63a. Thereby, the control pin 62 can be moved along the connecting groove 63a, and the switching dial 51 can be rotated to another mode selection position.

  The control groove 63 is provided with an attaching / detaching groove 63e corresponding to the attaching / detaching position of the switching dial 51. The attaching / detaching groove 63e is provided so as to be shifted in the circumferential direction with respect to the connecting groove 63a. As shown in FIG. 5A, when the switching dial 51 is in the attaching / detaching position, the control pin 62 is engaged with the attaching / detaching groove 63e. It comes to match. That is, the switching dial 51 can be attached to and detached from the case 12 by moving the control pin 62 to the attachment / detachment groove 63e. The attaching / detaching groove 63e is connected to the connecting groove 63a through the guide groove 63f. One end of the guide groove 63f is connected radially inward with respect to the connection groove 63a at a portion between the lock groove 63b and the lock groove 63c of the connection groove 63a, and the other end of the guide groove 63f is a detachable groove. It is connected with the edge part of the radial inside 63e. As shown in FIG. 5 (b), the switching dial 51 attached to the case 12 at the attaching / detaching position is rotated while operating the lock release button 61, and the control pin 62 is connected to the connecting groove 63a from the attaching / detaching groove 63e through the guide groove 63f. By moving to, the switching dial 51 is attached to the case 12 so that the mode can be selected.

  On the other hand, in the hammer drill 11 of the present invention, when the switching dial 51 is rotated for switching the operation mode, the switching dial 51 is prevented from unexpectedly rotating to the attaching / detaching position and being detached from the case 12. In the control groove 63, three drop-off prevention means are provided.

  As a first drop-off preventing means, the control groove 63 includes a first protrusion as a locking protrusion adjacent to a communicating portion of the guide groove 63f with the connecting groove 63a, that is, an entrance portion of the guide groove 63f from the connecting groove 63a. 71 is provided. The first protrusion 71 protrudes radially outward from the radially inner side surface of the coupling groove 63a between the notched portion and the guide groove 63f by cutting out the radially inner side surface of the coupling groove 63a in a wedge shape. It is formed in a convex shape. The surface of the first protrusion 71 facing the lock groove 63c is perpendicular to the radially inner side surface of the connecting groove 63a.

  Even if the switching dial 51 is rotated from the rotation hitting mode selection position or the hitting mode selection position toward the rotation mode selection position by the first protrusion 71, the control pin 62 can be rotated. Entering the guide groove 63f is prevented. That is, as shown in FIG. 8A, when the lock release button 61 is pressed, the control pin 62 moves along the radially inner side surface of the connecting groove 63a between the lock groove 63c and the lock groove 63b. However, since the first protrusion 71 is provided on the radially inner side surface of the connecting groove 63a, the control pin 62 comes into contact with the first protrusion 71, and further rotation of the switching dial 51 is prevented. Further, in order to further rotate the switching dial 51 toward the rotation mode selection position from this state, it is necessary to release the push of the lock release button 61. When the switch dial 51 is rotated toward the rotation mode selection position with the unlock button 61 released, the control pin 62 moves along the radially outer surface of the connecting groove 63a. 62 does not enter the guide groove 63f. When the switching dial 51 is moved to the rotation mode selection position, the control pin 62 is engaged with the lock groove 63b, and the switching dial 51 is held at the rotation mode selection position.

  As described above, in the hammer drill 11 of the present invention, the first protrusion 71 is provided adjacent to the communicating portion of the guide groove 63f with the connecting groove 63a, so that the switching dial 51 of the switching dial 51 is kept pressed. Even if the rotation operation is performed, the control pin 62 can be prevented from unexpectedly entering the guide groove 63f from the connection groove 63a. Therefore, it is possible to prevent the switching dial 51 from being unexpectedly rotated to the attachment / detachment position and falling off the case 12.

  As a second drop prevention means, the control groove 63 employs a structure in which a guide groove 63f is connected to the connecting groove 63a between the lock groove 63b and the lock groove 63c. That is, in the present invention, the entrance portion of the guide groove 63f from the connecting groove 63a is disposed between the lock groove 63b and the lock groove 63c. With this structure, a convex second protrusion 72 protruding in the circumferential direction is formed between the lock groove 63b and the guide groove 63f.

  Since the second protrusion 72 is provided, in order to rotate the switching dial 51 to the attachment / detachment position, as shown in FIG. 8B, the switching dial 51 is attached / detached to / from the connecting groove 63a. Rotation is performed in the direction opposite to the attachment / detachment position from the rotation mode selection position, which is the end portion on the position side, and then the lock release button 61 is pressed to cause the control pin 62 to enter the guide groove 63f. An operation for rotating the lens toward the attachment / detachment position is required. Since such a complicated operation is required, the switching dial 51 is prevented from being unexpectedly rotated to the attachment / detachment position.

  Thus, in the hammer drill 11 of the present invention, since the second protrusion 72 is provided between the lock groove 63b and the guide groove 63f, the switching dial 51 is unexpectedly rotated to the attachment / detachment position, and from the case 12. It can be prevented from falling off.

  Further, since the second protrusion 72 is provided, even when the lock release button 61 is pressed for the mode switching operation when the switching dial 51 is at the rotation mode selection position, the control pin 62 is moved to the second protrusion 72. It is prevented from coming into contact with the guide groove 63f directly by contact.

  Even if the control pin 62 enters the guide groove 63f by rotating the switching dial 51 from the rotation mode selection position to the rotation hitting mode selection position while the lock release button 61 is pressed, in this case Since the operator intends to rotate the switching dial 51 toward the rotation hitting mode selection position, the control pin 62 returns to the connecting groove 63a when the lock release button 61 is released. Thus, it does not unexpectedly move to the attaching / detaching groove 63e.

  As a third drop-off preventing means, the control groove 63 employs a structure in which the guide groove 63f is bent in a crank shape between the connecting groove 63a and the attaching / detaching groove 63e. With this structure, a convex third protrusion 73 projecting radially outward is formed on the radially inner side surface of the guide groove 63f, and a convex shape projecting radially inward is formed on the radially outer surface of the guide groove 63f. The fourth protrusion 74 is formed so as to be shifted in the circumferential direction with respect to the third protrusion 73.

  Since the guide groove 63f is formed in a crank shape by the third protrusion 73 and the fourth protrusion 74, even if the control pin 62 unexpectedly enters the guide groove 63f from the connecting groove 63a, the control pin 62 remains as it is as the detachable groove 63e. It is prevented that it moves to. That is, as shown in FIG. 8C, in order to move the control pin 62 to the attaching / detaching groove 63e even if the control pin 62 enters the guide groove 63f, the switching dial 51 is rotated toward the attaching / detaching position. Next, release of the lock release button 61 is released, the switching dial 51 is rotated again toward the attachment / detachment position, the lock release button 61 is then pressed again, the switching dial 51 is rotated again toward the attachment / detachment position, and the lock is further locked. A complicated operation of releasing the pressing of the release button 61 is required. Therefore, even if the control pin 62 unexpectedly enters the guide groove 63f from the connecting groove 63a, the control pin 62 does not easily move to the attaching / detaching groove 63e.

  Thus, in the hammer drill 11 of the present invention, the guide groove 63f is formed in a crank shape having the third protrusion 73 and the fourth protrusion 74, so that the control pin 62 that has entered the guide groove 63f is attached to the attachment / detachment groove 63e. It is possible to prevent the switching dial 51 from being unexpectedly rotated to the attaching / detaching position and dropping off from the case 12.

  As described above, the switching dial 51 is rotatably attached to the case 12 by inserting the attachment boss portion 51 c into the attachment hole 53 provided in the case 12 and rotating it. Further, the control pin 62 provided on the lock release button 61 of the switching dial 51 is engaged with the control groove 63 provided on the case 12 to control the rotation of the switching dial 51, and the control groove 63 is a means for preventing dropping. The first protrusion 71, the second protrusion 72, the third protrusion 73, and the fourth protrusion 74 are provided to prevent the control pin 62 from unexpectedly moving from the connecting groove 63a to the attaching / detaching groove 63e. Therefore, even if the switching dial 51 is easily attached to the case 12 by the engagement between the mounting boss 51c and the mounting hole 53, the switching dial 51 can be prevented from unexpectedly falling off the case 12.

  As described above, in the hammer drill 11 of the present invention, the mounting boss 51c provided on the switching dial 51 is inserted into the mounting hole 53 of the case 12, and the switching dial 51 is rotated while the lock release button 61 is operated. Therefore, a complicated operation such as attaching a retaining ring inside the case 12 is unnecessary, and the attaching operation of the switching dial 51 to the case 12 can be facilitated.

  Further, the control groove 63 is provided with the first protrusion 71, the second protrusion 72, the third protrusion 73, and the fourth protrusion 74, which are drop-off prevention means, so that the control pin 62 can be moved when the switching dial 51 is rotated. Since the movement from the connecting groove 63a to the attaching / detaching groove 63e is prevented, it is possible to prevent the switching dial 51 from being accidentally dropped from the case 12 during the operation mode switching operation.

  Next, a modified example of the present invention will be described.

  In the case shown in FIG. 4, the control groove 63 is provided with three dropout prevention means, but only one of each dropout prevention means may be provided.

  For example, as shown in FIG. 9A, the control groove 63 may be provided with only the first protrusion 71 that is a locking protrusion. Further, as shown in FIG. 9B, the control groove 63 is provided with a structure in which the guide groove 63f is connected to the connection groove 63a between the lock groove 63b and the lock groove 63c, that is, only the second protrusion 72 is provided. May be. Furthermore, as shown in FIG. 9C, the control groove 63 may be provided with only the structure of the guide groove 63f bent in a crank shape, that is, the third protrusion 73 and the fourth protrusion 74.

  In FIG. 9, members corresponding to the members described above are denoted by the same reference numerals.

  It goes without saying that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, in the above embodiment, the hammer drill 11 is described as an electric tool to which the present invention is applied. However, the present invention is not limited to this, and any electric tool capable of switching the operation mode may be used for other electric tools. The invention may be applied.

  Moreover, in the said embodiment, although the hammer drill 11 can be switched to three operation modes, it is not restricted to this, For example, this hammer drill is switchable only to two modes, a rotation mode and a rotation impact mode. The invention may be applied.

  Furthermore, in the said embodiment, although the switching member is comprised as the circular switching dial 51, it is not restricted to this, For example, you may make it comprise in another shape, such as a switching lever formed in lever shape. Good.

  Furthermore, in the above-described embodiment, the mounting structure of the switching dial 51 to the case 12 by the mounting boss 51c and the mounting hole 53 includes four locking pieces 51d and 51e and notches 53a and 53b. However, the present invention is not limited to this, and any other structure may be adopted as long as the switching dial 51 can be attached to and detached from the case 12 at the attachment / detachment position and is held by the case 12 by being rotated from there. May be.

11 Hammer drill (electric tool)
12 Case 12a First case half 12b Second case half 13 Handle portion 14 Electric motor 14a Output shaft 15, 16 Bearing 17 Fan 18 Controller 19 Power cord 21 Switch mechanism 22 Trigger 23 Tool mounting portion 24 Tip tool 31 Power conversion Mechanism 32 Intermediate shaft 33 Bearing 34 Input gear 35 First pinion 36 Reciprocating bearing 36a Inner ring 36b Outer ring 36c Rolling element 36d Output pin 37 Clutch member 38 Piston 39 Strike element 41 Intermediate element 42 Air chamber 43 Pinion sleeve 44 Second pinion 44a Ridge 45 Cylinder Rotation transmission sleeve)
46 Output gear 47 Spring 48 Switching sleeve 51 Switching dial (switching member)
51a Base 51b Knob 51c Mounting boss 51d, 51e Locking piece 51f Projection 52 Mounting recess 53 Mounting hole 53a, 53b Notch 61 Lock release button 62 Control pin 63 Control groove 63a Connection groove 63b, 63c, 63d Lock groove 63e Detachable groove 63f Guide groove 64 Spring 71 First protrusion (locking protrusion)
72 2nd protrusion 73 3rd protrusion 74 4th protrusion

Claims (5)

An electric tool for driving a tip tool by an electric motor,
A case for housing the electric motor;
A power conversion mechanism that is housed in the case and selectively converts the output of the electric motor into a plurality of types of motion and transmits the motion to the tip tool;
A switching member that is rotatably attached to the case and is rotated to switch a power conversion mode of the power conversion mechanism;
A lock release button provided on the switching member with a control pin protruding toward the case and biased radially outward;
A control groove provided in the case and engaged with the control pin to control the operation of the switching member;
The switching member is
Becomes detachable from the mounting hole of the case when a detachable position, provided with a mounting boss portion to be engaged to the case by rotating from the detachable position, engaging into the casing of the mounting boss portion The switching member is attached to the case by stopping,
The control groove is
An arc-shaped connecting groove centered on the axis of the mounting hole;
A plurality of locking grooves that are linked to the connecting groove toward the radially outer side, and that engage with the control pin when the switching member is in a position corresponding to each mode;
The control pin is provided at a position shifted in the circumferential direction with respect to the connecting groove, and is connected to the connecting groove via a guide groove connected to a radially inner side of the connecting groove so that the switching member is in the attaching / detaching position. A detachable groove with which
Drop-off preventing means for preventing the switch member from dropping from the case by preventing the control pin from moving from the connecting groove to the detachable groove when the switch member is rotated. An electric tool characterized by that.   2. The electric tool according to claim 1, wherein the power conversion mechanism is a three-mode type that converts the output of the electric motor into a rotary motion, a rotary impact motion, or an impact motion and transmits the converted output to the tip tool.   The drop-off prevention means is a locking projection that is provided adjacent to a communication portion of the guide groove with the connection groove and protrudes radially outward from a radially inner side surface of the connection groove. Item 3. The electric tool according to Item 1 or 2.   The electric tool according to any one of claims 1 to 3, wherein the drop-off prevention means has a structure in which the guide groove is connected to the connection groove between two lock grooves.   The electric tool according to any one of claims 1 to 4, wherein the drop-off prevention means has a structure in which the guide groove is bent in a crank shape between the connection groove and the attachment / detachment groove. .

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