JP6606941B2 - Portable power tool - Google Patents

Description

  The present invention relates to a portable power tool having a plurality of operation modes, and more particularly to a portable power tool having a feature in a mode switching unit for switching the operation mode.

  Portable power tools with multiple modes of operation are known. For example, a power tool having a plurality of power modes for switching the output of a motor according to work contents is known. Such a power tool includes a mode switching unit for switching the operation mode. For example, Patent Document 1 discloses a portable power tool that can switch the rotation speed of a motor by a dial operation.

Japanese Patent No. 5323364

  However, in the portable power tool described in Patent Document 1 described above, a speed change dial for switching the operation mode is provided to protrude rearward of the tool. For this reason, there is a possibility that the speed change dial is erroneously operated by an unintended contact from the outside.

  Then, this invention makes it a subject to provide the portable power tool which can prevent that the mode switching part for switching an operation mode is erroneously operated by the unintended contact from the outside.

  The present invention has been made to solve the above-described problems, and is characterized by the following.

The invention according to claim 1 is a portable type comprising a housing and a mode switching unit arranged on the surface of the housing, and configured to switch a plurality of operation modes when the mode switching unit is operated. The power tool, wherein the plurality of operation modes include a plurality of power modes with different motor outputs or a plurality of modes with different presence or absence of striking with a tip tool, and the housing is a power source of the portable power tool A battery mounting portion for attaching the battery to be mounted, and an output portion provided at an upper portion of the battery mounting portion, and a gap portion formed by surfaces facing each other , and the mode switching portion is provided in the gap portion, The mode switching unit includes an operation member exposed to be operable, and a switch pressed by the operation member,
The operation member includes a button unit that is pushed in by a user's finger, and a pressing unit that acts on the switch when the button unit is operated. Is also provided on the center side of the tool body, that is, on the vertical surface side passing through the output shaft of the tip tool .

The invention according to claim 2 includes a housing and a mode switching unit disposed on a surface of the housing, and is configured to switch a plurality of operation modes when the mode switching unit is operated. The plurality of operation modes include a plurality of power modes having different motor outputs, or a plurality of modes having different strikes by a tip tool, and the housing grips the portable power tool. A gap portion formed by faces facing each other inside the grip portion, and the mode switching portion is provided in the gap portion. The mode switching portion includes an operation member exposed to be operable and the operation member. A switch that is pressed by the button, and the operating member includes a button unit that is pressed by a user's finger, and the button unit is operated. And a pressing portion that acts on the switch, and the pressing portion is provided on the center side of the tool body from the button portion, that is, on the vertical plane side passing through the output shaft of the tip tool. And

The invention described in claim 3 includes a mode display unit for displaying the operation mode in addition to the feature of the invention described in claim 1 or 2 , and includes the mode switching unit and the mode display unit. It is provided on different surfaces.

The present invention is as described above, and the housing includes a gap portion formed by surfaces facing each other, and a mode switching portion is provided in the gap portion. According to such a configuration, the mode switching unit is not provided on the surface of the tool body, and in order to operate the mode switching unit, it is necessary to operate by inserting an operator's finger or the like into the gap. Accordingly, it is possible to prevent erroneous operation due to unintended contact from the outside.

  Even if the portable power tool is placed on a flat surface with the mode switching portion facing down, the mode switching portion does not face the flat surface. Therefore, the problem that the mode switching unit is pressed against the ground and operated unintentionally can also be prevented.

The invention according to claim 1 is as described above, and the mode switching unit is provided between the battery mounting unit and the output unit. According to such a configuration, since the mode switching unit can be arranged using the gap between the battery mounting unit and the output unit, the mode switching unit can be arranged in the gap without increasing the size of the machine.

The invention according to claim 2 is as described above, and the mode switching portion is provided on the opposing surface of the grip portion. According to such a configuration, since the mode switching unit can be arranged using a gap into which a finger is inserted when gripping the grip unit, the mode switching unit can be arranged in the gap unit without increasing the size of the machine.

Further, the invention according to claim 3 is as described above, and includes a mode display unit for displaying the operation mode, and the mode switching unit and the mode display unit are provided on different surfaces. According to such a configuration, even when the mode switching unit is arranged in the gap portion of the tool body, the mode display unit can be arranged on the surface (other than the gap portion) of the tool body, so that the visibility of the mode display unit is improved. be able to.

  Further, by arranging the mode switching unit and the mode display unit in different places, it is possible to avoid the problem that the operator's finger covers the mode display unit when operating the mode switching unit. Therefore, the visibility of the mode display part at the time of operation improves.

In addition, the present invention is as described above, and the mode switching unit includes an operation member exposed to be operable and a switch pressed by the operation member, and the operation member is pushed by a user's finger. A button portion to be operated; and a pressing portion that acts on the switch when the button portion is operated. The pressing portion is provided closer to the center of the tool body than the button portion. . According to such a configuration, the button unit operated by the finger and the switch can be shifted and arranged. When the button part and the switch are arranged so as to overlap each other, the height of the gap for inserting a finger is required in addition to the height of the switch, so that the overall height of the machine needs to be increased. In this regard, if the button part and the switch are shifted and arranged as in the present invention, a large gap for inserting a finger can be secured on the surface side of the tool body, and a switch having a height on the center side of the tool body. Can be arranged. Therefore, the mode switching part can be arranged in the gap of the tool body without increasing the overall height of the machine.

It is an external view of a portable power tool. It is a left view of a portable power tool. It is a front view of a portable power tool. (A) The figure which shows the internal structure of a portable power tool, (b) It is an AA sectional view. It is an exploded view of a control circuit board and a board case. It is a right view of a portable power tool. It is a partially expanded sectional view in the BB line of a portable power tool. (A) The external view of the portable power tool which concerns on a 1st modification, (b) The external view of the portable power tool which concerns on a 2nd modification.

  Embodiments of the present invention will be described with reference to the drawings. In the following description, “front” means the output direction of the portable power tool 10 (the tip direction in which the tip tool protrudes).

  The portable power tool 10 according to the present embodiment is a hammer drill that generates a hit by reciprocating a tip tool. As shown in FIGS. 1-3, the tip part of this portable power tool 10 is provided with a tip tool attaching part 10a to which a tip tool (not shown) such as a drill bit or a bull point can be attached and detached. After the tip tool is attached to the tip tool attaching portion 10a, the tip tool is pressed against an object such as concrete or stone and the portable power tool 10 is driven, so that the tip tool can perform drilling or crushing. In the present embodiment, a hammer drill will be described as an example. However, the embodiment of the present invention is not limited to the hammer drill, and other types of portable power tools 10 may be used.

  As shown in FIG. 4, the portable power tool 10 includes a housing 11, a motor 25, an output unit 29, a fan 26, a trigger switch 28, a battery connector 27, a battery 60, and a control circuit board 30. And.

  The housing 11 is a case member that covers the portable power tool 10, and includes a main body housing 12 that covers the front side of the machine, and a grip housing 13 that is connected to the rear portion of the main body housing 12.

  The main body housing 12 includes a mechanism accommodating portion 12a that accommodates the output portion 29, a motor accommodating portion 12b that is connected to the rear of the mechanism accommodating portion 12a, a battery mounting portion 12c that is provided below the mechanism accommodating portion 12a, and Is provided.

  The mechanism accommodating portion 12a is a cone-shaped portion that accommodates the output portion 29, and is joined to the motor accommodating portion 12b in a state where the inside is sealed.

  The motor accommodating portion 12 b is a short cylindrical portion that accommodates the motor 25 and the fan 26. A slit (not shown) for taking in air from the outside when the fan 26 operates is formed on the side of the motor housing portion 12b. The slit communicates with an air inlet 11a, which will be described later, and is formed so that outside air taken in from the air inlet 11a passes through the slit and is introduced into the main body housing 12.

  The battery mounting part 12 c is a part for attaching the battery 60. The battery mounting portion 12c is disposed below the mechanism housing portion 12a so as to be aligned with the mechanism housing portion 12a, and is formed to protrude forward. A rail portion for guiding the sliding of the battery 60 is formed on the lower surface of the battery mounting portion 12c, and the battery 60 can be attached by sliding from the front.

  The control circuit board 30 and the battery connector 27 are accommodated in parallel in the battery mounting portion 12c. The battery connector 27 is disposed below the control circuit board 30.

  A wind window 11b is formed on the left side surface of the battery mounting portion 12c (the surface located on the left side when the machine is viewed from the front), as shown in FIG. The wind window 11b is an opening for discharging the cooling air generated by the fan 26 to the outside. In the present embodiment, as shown in FIG. 1, the wind window 11b is not formed on the right side surface. For this reason, since the wind window 11b does not face the body when holding the tool with the right hand, the cooling air is not blown to the body, and the user can use the tool comfortably.

  Further, as shown in FIG. 1, a mode display unit 55 is provided on the right side surface of the battery mounting unit 12c, and a mode switching unit 50 is provided on the upper surface of the battery mounting unit 12c. The portable power tool 10 according to the present embodiment includes a plurality of power modes as operation modes, and the power mode can be switched by operating the mode switching unit 50. The current power mode is displayed on the mode display unit 55 to notify the user. The mode display unit 55 according to the present embodiment includes an LED window 55a, and a lighting state of a display LED 33 described later can be visually recognized through the LED window 55a.

Specifically, the portable power tool 10 according to the present embodiment includes three power modes (strong mode, medium mode, and weak mode) in which the output of the motor 25 is different. When the mode switching unit 50 is pressed, the power mode is switched in the order of “strong mode” → “medium mode” → “weak mode”. When the mode switching unit 50 is pressed while the power mode is “weak mode”, the mode is changed to “strong mode”. The current power mode is displayed by the mode display section 55 (display LED 33). For example, the power mode is displayed by the number of display LEDs 33 that are lit. The power mode can be confirmed not only by the method of displaying the power mode by the number of display LEDs 33 to be lit, but by indicating which display LED 33 is lit and in what color the display LED 33 is lit. You may do it.

  In the present embodiment, the display LED 33 notifies a machine abnormality. For example, when the temperature of the machine becomes high, the display LED 33 may blink to notify the user that the machine cannot be used.

  Further, as shown in FIG. 3, an irradiation window portion 11c is provided on the front surface of the battery mounting portion 12c. The irradiation window portion 11c is provided to allow light from an irradiation LED 32 described later to pass therethrough. By irradiating light from the irradiation LED 32 from the irradiation window portion 11c, the work location can be brightened.

  The grip housing 13 includes a motor surrounding portion 13a, a grip portion 13b extending below the motor surrounding portion 13a, and a connecting portion 13c protruding forward from a lower end portion of the grip portion 13b.

  The motor surrounding portion 13 a is a bowl-shaped portion that is attached so as to cover the rear end of the motor housing portion 12 b of the main body housing 12. On the side of the motor surrounding portion 13a, an air inlet 11a is formed to take in air from the outside when the fan 26 is operated.

  The grip part 13 b is a part that an operator grips when using the portable power tool 10. A trigger switch 28, which will be described later, is accommodated in the grip portion 13b.

  The connecting portion 13c protrudes forward at a substantially right angle from the lower end portion of the grip portion 13b. A front end portion of the connecting portion 13c is rotatably connected to the main body housing 12 via a swivel joint 21.

  The main body housing 12 and the grip housing 13 are connected as follows.

  First, as shown in FIG. 4, the upper portion of the grip housing 13 (near the upper end of the motor surrounding portion 13a) is connected to the main body housing 12 via an elastic member 20 so as to be displaceable. The elastic member 20 is a compression spring that is compressed between the main body housing 12 and the grip housing 13. The elastic member 20 plays a role of absorbing vibration by elastic deformation when the main body housing 12 and the grip housing 13 move relative to each other.

  On the other hand, the lower portion of the grip housing 13 (the tip of the connecting portion 13c) is connected to the main body housing 12 through a joint 21 so as to be rotatable.

  By configuring in this way, even when the tip is pushed back by the reaction force of impact and a force to rotate the tool is applied, such reaction force is absorbed by the elastic member 20 and the swivel joint 21, It is difficult for vibration to be transmitted to the hand holding the grip portion 13b.

  The motor 25 is accommodated inside the housing 11 behind the portable power tool 10. The output shaft of the motor 25 is connected to an output unit 29 described later, and the rotational force of the motor 25 is transmitted to the output unit 29.

  The output unit 29 operates the tip tool using the motor 25 as a driving force, and is disposed in front of the motor 25. The output unit 29 has a built-in piston and operates using the motor 25 as a driving force. Specifically, when the motor 25 rotates, the rotational force is transmitted to the internal mechanism of the output unit 29, and the piston reciprocates by the driving force of the motor 25. A striker for hitting the tip tool is attached to the front end of the piston, and the tip tool is hit by the striker.

  Although not described in detail, the output unit 29 has a plurality of work modes. For example, it has a rotation / striking mode in which the tip tool strikes while rotating, and a rotation mode in which the tip tool performs only rotation without striking, and these work modes can be switched and used. ing. This work mode is switched by a mode switching lever 53 shown in FIG.

  The fan 26 is for supplying cooling air to the inside of the portable power tool 10 for cooling the motor 25 and the control circuit board 30. In the present embodiment, the fan 26 is provided between the motor 25 and the output unit 29. Has been placed. The fan 26 is connected to the output shaft of the motor 25 and rotates simultaneously when the motor 25 rotates. When the fan 26 rotates, outside air is sucked from the air inlet 11 a that opens to the side of the housing 11, and air in the housing 11 is discharged to the outside from the wind window 11 b that opens to the side of the housing 11. In other words, the cooling air generated by the fan 26 passes through the air path from the intake port 11a to the wind window 11b.

  The trigger switch 28 is an operation unit for operating the motor 25, and is disposed at a position where the index finger is applied when the grip unit 13b is gripped. When the trigger switch 28 is pulled, an operation signal for the trigger switch 28 is output to the control circuit board 30, and the control circuit board 30 controls the rotation of the motor 25 based on this operation signal.

  The battery connector 27 is for electrically connecting the battery 60 and includes a terminal portion connected to the battery 60. The battery connector 27 is built in the battery mounting portion 12c, and is arranged so that the terminal portion of the battery connector 27 is exposed on the lower surface of the battery mounting portion 12c.

  The battery 60 is a secondary battery that supplies power to the motor 25 and the control circuit board 30 and serves as a power source for the output unit 29. The battery 60 is a detachable battery 60 that can be attached to the battery mounting portion 12c of the housing 11, and can be charged by being removed from the battery mounting portion 12c.

  Although not shown in particular, when the battery 60 is slid to the battery mounting portion 12c, the battery 60 moves along the rail portion of the battery mounting portion 12c, and the latch of the battery 60 engages with the engaging recess of the battery mounting portion 12c. Thus, the battery 60 is fixed. When the battery 60 is fixed, the terminal portion of the battery connector 27 and the terminal portion of the battery 60 are electrically connected.

  The control circuit board 30 is for controlling the operation of the motor 25 and the like. As shown in FIG. 5, the control circuit board 30 includes FETs 31a to 31f for driving the motor 25, an irradiation LED 32 for irradiating the front of the machine, a display LED 33 for displaying a power mode, and a power mode. Electronic components such as a tact switch 34 for changing are mounted.

  The control circuit board 30 is disposed below the output unit 29 and above the battery 60 so as to be parallel to the axial direction of the tip tool. The accommodation space of the control circuit board 30 communicates with the accommodation space of the motor 25, the motor 25 is arranged on the wind of the cooling air generated by the fan 26, and the control circuit board 30 is arranged on the lee. The cooling air generated by the fan 26 flows along the upper surface of the control circuit board 30 and is guided to the wind window 11b.

  The control circuit board 30 described above is fixed to the housing 11 while being accommodated in a board case 40 as shown in FIG. As shown in FIG. 5, the substrate case 40 forms an accommodating portion 40 f for accommodating the control circuit substrate 30 by raising four wall portions 40 b to 40 e from four sides of the bottom plate portion 40 a. The board case 40 is formed so that the control circuit board 30 fits in the accommodating portion 40f. For example, notches 30a are formed at two locations on the outer periphery of the control circuit board 30, and the substrate case 40 is also cut away so as to correspond to the notches 30a. A first wiring guide 41 and a second wiring guide 42 are formed at the notch position. The first wiring guide 41 and the second wiring guide 42 are guide portions for wiring an electric wire connected to the control circuit board 30. The second wiring guide 42 is provided with a hook 42a for hooking an electric wire. Further, a third wiring guide 43 provided with a hook 43a is formed at a position different from these notch positions. The third wiring guide 43 is also a guide part for wiring an electric wire connected to the control circuit board 30.

  As shown in FIG. 4B, a screw fixing portion 44 is formed on the bottom portion of the substrate case 40 so as to protrude downward. The screw fixing portion 44 is a portion for fixing the substrate case 40 to the housing 11 with screws 48. The board case 40 is firmly fixed to the housing 11 by attaching the screw 48 so as to penetrate the screw fixing portion 44 and screwing the screw 48 to the housing 11.

  Note that the irradiation LED 32 and the display LED 33 mounted on the control circuit board 30 are arranged so as to irradiate light in directions orthogonal to each other, as shown in FIG. The light from the irradiation LED 32 is irradiated to the front of the machine through the irradiation window 11c (see FIG. 1 and the like). The light from the display LED 33 is irradiated to the right side of the machine through the LED window 55a (see FIG. 1 and the like).

  By the way, as described above, the portable power tool 10 according to the present embodiment includes the mode switching unit 50 on the surface of the housing 11, specifically, the upper surface of the battery mounting unit 12c. It is configured to switch between a plurality of power modes when operated. As shown in FIGS. 3 and 7, the upper surface of the battery mounting portion 12 c provided with the mode switching unit 50 is opposed to the lower surface of the mechanism housing portion 12 a that houses the output portion 29. For this reason, a gap S is formed between the battery mounting part 12c and the mechanism housing part 12a (output part 29). Since the mode switching unit 50 is provided in the gap S, the finger is inserted into the gap S when the mode switching unit 50 is operated.

  In addition, the upper surface of the battery mounting portion 12c is formed to be inclined so as to become lower from the center toward the side surface. For this reason, the gap width W in the vicinity of the opening into which the finger is inserted is formed large, and it is easy to insert the finger.

  As shown in FIG. 7, the mode switching unit 50 includes an operation member 51 that is exposed so as to be operable, and a tact switch 34 that is pressed by the operation member 51.

  The operation member 51 is a member that can be pressed downward, and is attached to the housing 11 so that the front surface is exposed to the outside and the back surface faces the control circuit board 30. The operation surface 51 a of the operation member 51 is provided with a button portion 51 b that is pushed in by a user's finger. Further, on the back side of the operation member 51, there is provided a pushing portion 51c that acts on the tact switch 34 when the button portion 51b is operated. The pushing portion 51 c is disposed so as to face the tact switch 34 on the control circuit board 30. The pushing portion 51c is provided closer to the center side of the tool body than the button portion 51b (vertical surface side passing through the output shaft of the output portion 29). With such an arrangement, the tall tact switch 34 can be arranged on the center side of the tool body.

  As shown in FIG. 7, the upper surface of the operation member 51 is inclined so as to gradually become lower from the pushing portion 51 c toward the button portion 51 b. In other words, the upper surface of the pushing portion 51c is higher than the upper surface of the button portion 51b. With such a configuration, a space is ensured downward in the pushing portion 51c, and a space is ensured upward in the button portion 51b. For this reason, even if the position of the control circuit board 30 is not lowered and the gap portion S is not enlarged, the tall tact switch 34 can be accommodated below the pushing portion 51c, and the finger is inserted above the button portion 51b. A gap width W for inserting is ensured.

  When the mode switching unit 50 is operated and the power mode is switched, the mode display unit 55 displays which mode has been changed. As shown in FIG. 1 and the like, the mode display unit 55 is provided on the right side surface of the tool body, and is provided on a different surface from the mode switching unit 50. For this reason, even when the mode switching unit 50 is operated, the operating hand does not cover the mode display unit 55, and the current power mode is easily visible. In the present embodiment, the LED window 55a of the mode display unit 55 and the operation member 51 of the mode switching unit 50 are arranged so as to be displaced from each other in the front-rear direction. Specifically, as shown in FIG. 6, the LED window 55 a of the mode display unit 55 is disposed behind the operation member 51 of the mode switching unit 50. As described above, the mode display unit 55 and the mode switching unit 50 are arranged so as to be offset from each other, thereby further preventing the mode display unit 55 from being covered with the operating hand, and the mode display unit 55 being visible Is increasing.

  As described above, according to the present embodiment, the housing 11 includes the gap portion S formed by the surfaces facing each other, and the mode switching portion 50 is provided in the gap portion S. According to such a configuration, the mode switching unit 50 is not provided on the surface of the tool body, and in order to operate the mode switching unit 50, it is necessary to operate by inserting an operator's finger or the like into the gap portion S. is there. Accordingly, it is possible to prevent erroneous operation due to unintended contact from the outside.

  Even if the portable power tool 10 is placed on a flat surface with the mode switching unit 50 facing down, the mode switching unit 50 does not face the flat surface. Therefore, the problem that the mode switching unit 50 is pressed against the ground and operated unintentionally can be prevented.

  Further, a mode switching unit 50 is provided between the battery mounting unit 12 c and the output unit 29. According to such a configuration, since the mode switching unit 50 can be arranged using the gap between the battery mounting unit 12c and the output unit 29, the mode switching unit 50 can be installed in the gap S without increasing the size of the machine. Can be placed.

  Moreover, the mode display part 55 for displaying an operation mode was provided, and the mode switch part 50 and the mode display part 55 were provided in the mutually different surface. According to such a configuration, even when the mode switching unit 50 is arranged in the gap S of the tool body, the mode display unit 55 can be arranged on the surface of the tool body (other than the gap S). Visibility can be improved.

  Further, by arranging the mode switching unit 50 and the mode display unit 55 in different places, a problem that the operator's finger covers the mode display unit 55 when operating the mode switching unit 50 can be avoided. it can. Therefore, the visibility of the mode display unit 55 during operation is improved.

  The mode switching unit 50 includes an operation member 51 exposed to be operable and a tact switch 34 that is pressed by the operation member 51. The operation member 51 is pressed by a user's finger. And a pushing part 51c that acts on the tact switch 34 when the button part 51b is operated, and the pushing part 51c is provided closer to the center of the tool body than the button part 51b. According to such a configuration, the button unit 51b operated by the finger and the tact switch 34 can be shifted and arranged. When the button part 51b and the tact switch 34 are arranged so as to overlap each other, the height of the gap width W for inserting a finger is required in addition to the height of the tact switch 34, so that the overall height of the machine is increased. There is a need. In this regard, if the button part 51b and the tact switch 34 are shifted and arranged as in the present embodiment, a large gap width W for inserting a finger can be secured on the surface side of the tool body, and the center side of the tool body can be secured. Then, a tact switch 34 having a height can be arranged. Therefore, the mode switching unit 50 can be disposed in the gap S of the tool body without increasing the overall height of the machine.

  In the above-described embodiment, the mode switching unit 50 is provided between the battery mounting unit 12 c and the output unit 29. However, the embodiment of the present invention is not limited to this, and the mode switching unit 50 may be provided in another place. For example, as shown in FIG. 8A or 8B, a mode switching unit 50 may be provided on the opposing surface of the grip portion 13b. According to such a configuration, since the mode switching unit 50 can be arranged using a gap into which a finger is inserted when gripping the grip unit 13b, the mode switching unit 50 is installed in the gap S without increasing the size of the machine. Can be placed.

  In the above-described embodiment, the power mode is switched when the mode switching unit 50 is operated. However, the present invention is not limited to this, and another operation mode is switched when the mode switching unit 50 is operated. It may be. For example, when the mode switching unit 50 is operated, the work mode (“rotation / hitting mode” “rotation mode”) may be switched.

DESCRIPTION OF SYMBOLS 10 Portable power tool 10a Tip tool attaching part 11 Housing 11a Air inlet 11b Air window 11c Irradiation window part 12 Main body housing 12a Mechanism accommodating part 12b Motor accommodating part 12c Battery mounting part 13 Grip housing 13a Motor surrounding part 13b Grip part 13c Connecting part DESCRIPTION OF SYMBOLS 20 Elastic member 21 Turning joint 25 Motor 26 Fan 27 Battery connector 28 Trigger switch 29 Output part 30 Control circuit board 30a Notch 31a-31f FET
32 LED for irradiation
33 LED for display
34 tact switch 40 substrate case 40a bottom plate portion 40b-40e wall portion 40f accommodating portion 41 first wiring guide 42 second wiring guide 42a hook 43 third wiring guide 43a hook 44 screw fixing portion 48 screw 50 mode switching portion 51 operation member 51a Operation surface 51b Button part 51c Pushing part 53 Mode switching lever 55 Mode display part 55a LED window 60 Battery S Gap part W Gap width

Claims (3)

A housing;
A mode switching portion disposed on the surface of the housing;
With
A portable power tool configured to switch a plurality of operation modes when the mode switching unit is operated,
The plurality of operation modes include a plurality of power modes with different motor outputs, or a plurality of modes with different presence or absence of hitting by a tip tool,
The housing includes a gap portion formed by surfaces facing each other by a battery mounting portion to which a battery serving as a power source of the portable power tool and an output portion provided at an upper portion of the battery mounting portion ,
The mode switching part is provided in the gap part ,
The mode switching unit includes an operation member exposed to be operable and a switch pressed by the operation member,
The operation member includes a button part that is pushed in by a user's finger, and a push part that acts on the switch when the button part is operated,
The portable power tool according to claim 1, wherein the pushing portion is provided on the center side of the tool body from the button portion, that is, on the vertical plane side passing through the output shaft of the tip tool. A housing;
A mode switching portion disposed on the surface of the housing;
With
A portable power tool configured to switch a plurality of operation modes when the mode switching unit is operated,
The plurality of operation modes include a plurality of power modes with different motor outputs, or a plurality of modes with different presence or absence of hitting by a tip tool,
The housing includes a gap formed by surfaces facing each other inside a grip portion for gripping the portable power tool ,
The mode switching part is provided in the gap part ,
The mode switching unit includes an operation member exposed to be operable and a switch pressed by the operation member,
The operation member includes a button part that is pushed in by a user's finger, and a push part that acts on the switch when the button part is operated,
The portable power tool according to claim 1, wherein the pushing portion is provided on the center side of the tool body from the button portion, that is, on the vertical plane side passing through the output shaft of the tip tool. A mode display for displaying the operation mode;
Characterized in that provided on the different surfaces and the mode switching unit and the mode display unit, according to claim 1 or 2 portable power tool according.

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