JP7514906B2 - Electric screwdriver - Google Patents

Description

The present invention relates to a power tool.

The power tool includes a motor that generates power to drive the tool tip, and a main switch that switches the motor on and off. The main switch includes a trigger operating member that is operated by the user of the power tool. The motor starts when the trigger operating member is operated. The trigger operating member is often provided on the handle portion of the power tool. The user of the power tool operates the trigger operating member while holding the handle portion to start the motor.

JP 2017-213625 A

The power tool also includes a mode change switch that changes the rotation speed of the motor. The mode change switch includes a mode operation member that is operated by a user of the power tool. The rotation speed of the motor is changed by operating the mode operation member. To prevent a decrease in operability of the power tool, it is desirable for the user of the power tool to be able to operate the mode operation member while holding the handle portion.

The objective of this aspect of the present invention is to prevent a decrease in the operability of a power tool.

According to an aspect of the present invention, there is provided an electric power tool comprising a main body including a motor, a handle connected to the main body, a trigger operating member disposed on the handle for starting the motor, and a mode operating member disposed on the handle for changing the rotation speed of the motor.

According to this aspect of the present invention, it is possible to suppress a decrease in the operability of the power tool.

FIG. 1 is a side view of a power tool according to a first embodiment, as viewed from the right. FIG. 2 is a front view of the power tool according to the first embodiment. FIG. 3 is a side cross-sectional view of the power tool according to the first embodiment. FIG. 4 is a cross-sectional view showing a part of the power tool according to the first embodiment. FIG. 5 is a functional block diagram showing the power tool according to the first embodiment. FIG. 6 is a perspective view of the power tool according to the first embodiment as viewed from the rear. FIG. 7 is a perspective view of the power tool according to the first embodiment as viewed from the front. FIG. 8 is a perspective view of the power tool according to the first embodiment as viewed from the rear. FIG. 9 is a side view of the power tool according to the first embodiment as viewed from the right. FIG. 10 is a perspective view of the power tool according to the first embodiment as viewed from the rear. FIG. 11 is a perspective view of the power tool according to the first embodiment as viewed from the front. FIG. 12 is a perspective view of the power tool according to the second embodiment as viewed from the front. FIG. 13 is a perspective view of the power tool according to the second embodiment as viewed from the rear. FIG. 14 is a perspective view of the power tool according to the third embodiment as viewed from the rear. FIG. 15 is a perspective view of the power tool according to the third embodiment, as viewed from the front. FIG. 16 is a perspective view of the power tool according to the fourth embodiment, as viewed from the rear. FIG. 17 is a perspective view of the power tool according to the fourth embodiment, as viewed from the front. FIG. 18 is a perspective view of the power tool according to the fifth embodiment, as viewed from the rear. FIG. 19 is a perspective view of the power tool according to the fifth embodiment, as viewed from the front. FIG. 20 is a perspective view of the power tool according to the sixth embodiment, as viewed from the rear. FIG. 21 is a perspective view of the power tool according to the sixth embodiment, as viewed from the front. FIG. 22 is a perspective view of the power tool according to the seventh embodiment, as viewed from the rear. FIG. 23 is a diagram showing a mode operation member according to the seventh embodiment. FIG. 24 is a diagram showing a mode operation member according to the seventh embodiment. FIG. 25 is a diagram showing a mode operation member according to the seventh embodiment.

The following describes an embodiment of the present invention with reference to the drawings, but the present invention is not limited to this. The components of the embodiments described below can be combined as appropriate. Also, some components may not be used.

In the following explanation, an XYZ Cartesian coordinate system is set, and the positional relationship of each part is explained with reference to this XYZ Cartesian coordinate system. The direction parallel to the X-axis (first axis) in a specified plane is the X-axis direction (first axis direction), the direction parallel to the Y-axis (second axis) in a specified plane perpendicular to the X-axis is the Y-axis direction (second axis direction), and the direction parallel to the Z-axis (third axis) perpendicular to the X-axis and Y-axis is the Z-axis direction (third axis direction). In addition, the direction of rotation or tilt around the X-axis is the θX direction, the direction of rotation or tilt around the Y-axis is the θY direction, and the direction of rotation or tilt around the Z-axis is the θZ direction.

For the sake of convenience, in the following explanation, the X-axis direction is the front-to-back direction, the Y-axis direction is the up-down direction, and the Z-axis direction is the left-to-right direction. The +X direction is the front direction, the -X direction is the rear direction, the +Y direction is the up direction, the -Y direction is the down direction, the +Z direction is the right direction, and the -Z direction is the left direction.

[First embodiment]
A first embodiment will be described. Fig. 1 is a side view of a power tool 1A according to the present embodiment as seen from the right. Fig. 2 is a front view of the power tool 1A according to the present embodiment as seen from the front. Fig. 3 is a side cross-sectional view of the power tool 1A according to the present embodiment.

In this embodiment, the power tool 1A is an impact driver. The power tool 1A includes a main body 4 including a motor 11, a handle 6 connected to the main body 4, a battery mounting section 29 to which a battery 31 is attached, a forward/reverse switch 28 operated to change the direction of rotation of the motor 11, a main switch 7 that starts the motor 11, a mode change switch 140 that changes the rotation speed of the motor 11, and a control device 33.

The power tool 1A also includes a housing 2 that defines at least a portion of the surfaces of the main body 4, the handle 6, and the battery mounting portion 29. The surface of the power tool 1A includes the surface of the housing 2.

The housing 2 includes a motor housing 2A that houses the motor 11, a handle housing 2B that is connected to the lower part of the motor housing 2A, and a battery mounting housing 2C that is connected to the lower part of the handle housing 2B. The surface of the main body 4 includes the surface of the motor housing 2A. The surface of the handle portion 6 includes the surface of the handle housing 2B. The surface of the battery mounting portion 29 includes the surface of the battery mounting housing 2C.

The rotation axis AX of the motor 11 is parallel to the X axis. The main body 4 extends in the X axis direction. The handle 6 is connected to the lower part of the main body 4. The handle 6 extends in the -Y direction perpendicular to the rotation axis AX of the motor 11. The battery attachment part 29 is connected to the lower part of the handle 6. In the Y axis direction, the handle 6 is disposed between the main body 4 and the battery attachment part 29.

In the XZ plane perpendicular to the Y axis, the outer shape of the main body 4 is larger than the outer shape of the handle 6. As shown in Figures 1 and 2, in the X-axis direction, the dimension L4 of the main body 4 is larger than the dimension L6 of the handle 6. In the Z-axis direction, the dimension W4 of the main body 4 is larger than the dimension W6 of the handle 6.

In the XZ plane perpendicular to the Y axis, the outer shape of the battery mounting section 29 is larger than the outer shape of the handle section 6. As shown in Figures 1 and 2, in the X-axis direction, the dimension L29 of the battery mounting section 29 is larger than the dimension L6 of the handle section 6. In the Z-axis direction, the dimension W29 of the battery mounting section 29 is larger than the dimension W6 of the handle section 6.

The dimension L4 of the main body 4 is greater than the dimension L29 of the battery mounting section 29. The dimension W4 of the main body 4 is smaller than the dimension W29 of the battery mounting section 29.

As shown in FIG. 1, in the XY plane, the surface of the main body 4 and the surface of the handle 6 are connected via an inflection point Ca. The surface of the handle 6 and the surface of the battery mounting section 29 are connected via an inflection point Cb.

As shown in FIG. 2, in the YZ plane, the surface of the main body 4 and the surface of the handle 6 are connected via an inflection point Cc. The surface of the handle 6 and the surface of the battery mounting section 29 are connected via an inflection point Cd.

The upper end of the handle portion 6 includes the inflection points Ca and Cc. The lower end of the handle portion 6 includes the inflection points Cb and Cd. The main body portion 4 is the portion above the inflection points Ca and Cc. The handle portion 6 is the portion between the inflection points Ca and Cc and the inflection points Cb and Cd. The battery attachment portion 29 is the portion below the inflection points Cb and Cd.

<Main body>
The main body 4 holds and drives a tool tip, such as a driver bit. As shown in Figures 1, 2, and 3, the main body 4 includes a fan 10, a motor 11, a speed reduction mechanism 12, a spindle 13, a spring 14, a hammer 16, an anvil 17, a motor housing 2A, a rear housing 20, a front housing 26, a hammer case 21, a bumper 27, and a headlight 160.

The housing 2 of the main body 4 includes a motor housing 2A, a rear housing 20, and a front housing 26.

The motor housing 2A is a cylindrical member. The motor housing 2A is disposed around the motor 11. The central axis of the motor housing 2A is substantially parallel to the X-axis. An opening is provided at each of the front end and rear end of the motor housing 2A. The rear housing 20 is disposed so as to close the opening at the rear end of the motor housing 2A. The front housing 26 is a cylindrical member and is connected to the front end of the motor housing 2A. The hammer case 21 is disposed around the hammer 16. The hammer case 21 is disposed inside the motor housing 2A and the front housing 26. The motor housing 2A and the front housing 26 are disposed around the hammer case 21. The bumper 27 is a cylindrical member formed of an elastic body and is connected to the front end of the hammer case 21.

The motor 11 generates power to drive the tool. The motor 11 is an electric motor that operates with power supplied from the battery 31. The motor 11 is housed inside the motor housing 2A.

The motor 11 is a brushless motor. The motor 11 includes a cylindrical stator 51 and a rotor 52 disposed inside the stator 51. The rotation axis AX of the motor 11 is parallel to the X-axis. The rotor 52 rotates about the rotation axis AX.

The stator 51 has a stator core 54 with multiple internal teeth, a front insulating member 56 arranged in front of the stator core 54, a rear insulating member 58 arranged behind the stator core 54, and multiple coils 60 wound around the internal teeth of the stator core 54 via the front insulating member 56 and the rear insulating member 58.

The stator 51 also has a sensor board 62 fixed to the front insulating member 56, and a coil connection portion disposed on the periphery of the front insulating member 56 and connecting the coil 60 to the sensor board 62. A number of magnetic sensors are fixed to the front surface of the sensor board 62. The coil connection portion is connected to the control device 33 via a terminal portion 64.

The rotor 52 has a motor shaft 66, a rotor core 68 arranged around the motor shaft 66, a permanent magnet 70 arranged around the rotor core 68, and a sleeve 72 arranged around the motor shaft 66 forward of the rotor core 68.

The motor shaft 66 is rotatably supported by a motor front bearing 74 and a motor rear bearing 77. The motor front bearing 74 is disposed in an opening of the bearing retainer 75 and is supported by the bearing retainer 75. The motor rear bearing 77 is held in the rear housing 20. A pinion gear 76 is fixed to the front end of the motor shaft 66.

The fan 10 is disposed behind the motor 11. The fan 10 is a centrifugal fan having multiple blades, and is fixed to the motor shaft 66 via a fan sleeve 78. When the motor 11 is operated, the fan 10 rotates around the rotation axis AX. A plurality of air intakes 25 are provided in the motor housing 2A. A plurality of exhaust ports 24 are provided in the rear housing 20. The air intakes 25 are provided forward of the fan 10. The exhaust ports 24 are provided around the fan 10. When the fan 10 rotates, air outside the motor housing 2A flows into the motor housing 2A through the air intakes 25. The air that flows into the motor housing 2A cools the motor 11. The air that has absorbed heat from the motor 11 is discharged to the outside of the rear housing 20 through the exhaust ports 24.

The reduction mechanism 12 transmits the rotational force of the rotor 52 to the spindle 13. The reduction mechanism 12 rotates the spindle 13 so that the rotation speed of the spindle 13 per unit time is lower than the rotation speed of the rotor 52. The reduction mechanism 12 includes a planetary gear mechanism, and has a ring-shaped internal gear 80, a plurality of planetary gears 82 that mesh with the internal gear 80, and a plurality of pins 84 that rotatably support each of the plurality of planetary gears 82.

The internal gear 80 is disposed inside the hammer case 21 and is fixed to the inner surface of the rear end of the hammer case 21. A number of planetary gears 82 are disposed inside the internal gear 80.

The spindle 13 is disposed forward of the motor 11. The spindle 13 is connected to the motor shaft 66 of the rotor 52 via the reduction mechanism 12. The power generated by the motor 11 is transmitted to the spindle 13 via the reduction mechanism 12. When the motor 11 is operated, the spindle 13 rotates about the rotation axis AX.

The spindle 13 has a disk portion 90, a front rod portion that protrudes forward from the disk portion 90, and a rear rod portion that protrudes rearward from the disk portion 90. In the YZ plane perpendicular to the rotation axis AX, the outer shape of the disk portion 90 is larger than the outer shapes of the front rod portion and the rear rod portion.

The bearing retainer 75 is disposed around the rear rod portion of the spindle 13. The bearing retainer 75 is supported by a housing rib 96 formed inside the motor housing 2A. A spindle bearing 94 is disposed between the bearing retainer 75 and the rear rod portion of the spindle 13. The spindle 13 is rotatably supported by the spindle bearing 94.

The bearing retainer 75 has a retainer rib 98 that protrudes outward in the radial direction of the rotation axis AX. The retainer rib 98 is disposed between the rear end of the hammer case 21 and the front surface of the housing rib 96.

The front part of the bearing retainer 75 is positioned between the rear end of the inner surface of the hammer case 21 and the outer surface of the internal gear 80.

The inner diameter of the spindle bearing 94 is larger than the inner diameter of the motor front bearing 74 supported by the bearing retainer 75. In the front-to-rear direction, the position of the spindle bearing 94 differs from the position of the motor front bearing 74. The spindle bearing 94 is positioned forward of the motor front bearing 74. This prevents the force transmitted from the spindle 13 to the spindle bearing 94 from being transmitted to the motor front bearing 74.

The spindle 13 has an inner hole 100 therein. The rear of the inner hole 100 is connected to the hollow portion of the disk portion 90. The front end of the motor shaft 66 and the pinion gear 76 are disposed in the rear of the inner hole 100. The planetary gear 82 of the reduction mechanism 12 is disposed in the hollow portion of the disk portion 90. The pinion gear 76 and the planetary gear 82 mesh with each other. This allows the rotational force of the rotor 52 to be transmitted to the spindle 13 via the reduction mechanism 12.

The hammer 16 is positioned forward of the spindle 13. The hammer 16 includes a rotary impact mechanism and converts the rotational force of the spindle 13 into a rotary impact force. The rotary impact force of the hammer 16 is transmitted to the anvil 17.

The hammer 16 has a recess 101 on its rear surface. The front part of the spring 14 is disposed in the recess 101. The front end part of the spring 14 is supported on the inner surface of the recess 101 via a number of spring balls 102 and a hammer washer 104. A hammer ball 106 is disposed between the hammer 16 and the front part of the spindle 13. The hammer ball 106 guides the hammer 16 in the forward and backward directions when the hammer 16 strikes.

The spring 14 is a coil-shaped elastic member. The spring 14 is disposed between the disk portion 90 of the spindle 13 and the hammer 16. The spring 14 reduces the rotational impact force transmitted from the hammer 16 to the anvil 17.

The anvil 17 holds the tool tip and rotates around the rotation axis AX based on the rotary impact force transmitted from the hammer 16. The anvil 17 holds a driver bit as the tool tip, allowing the power tool 1A to perform screw tightening.

The anvil 17 has an anvil hole 120 in which at least a portion of the tool tip is placed, a chuck 112 that secures the tool tip placed in the anvil hole 120, a flange portion 114 that protrudes outward in the radial direction of the rotation axis AX, and a rear hole into which the front end portion 118 of the spindle 13 is inserted.

The anvil 17 is rotatably supported by the anvil bearing 116. The anvil bearing 116 is positioned forward of the flange portion 114. The anvil bearing 116 is supported by the front part of the inner surface of the hammer case 21.

The chuck 112 has a chuck sleeve 122, a chuck spring 124, a chuck washer 126, a chuck spring fixing member 127, and a number of chuck balls 128.

The chuck sleeve 122 is a cylindrical member. The chuck sleeve 122 has a chuck front hole portion 130 arranged around the anvil 17 and a chuck ball fixing portion 132 that protrudes inward from the inner surface of the chuck front hole portion 130.

The chuck spring 124 is disposed in the chuck front hole portion 130. The chuck washer 126 is disposed in front of the chuck spring 124. The chuck spring fixing member 127 is fixed to the outer surface of the anvil 17 in front of the chuck washer 126. The chuck spring 124 is disposed in a space defined by the outer surface of the anvil 17, the chuck washer 126, and the inner surface of the chuck front hole portion 130. The chuck ball 128 is exposed to the inside of the anvil hole 120. The chuck ball 128 is contactable with the chuck ball fixing portion 132.

A user of the power tool 1A can operate the chuck sleeve 122. When the chuck sleeve 122 is moved forward, the chuck sleeve 122 moves forward while receiving the elastic force of the chuck spring 124. When the chuck sleeve 122 moves forward, the chuck ball fixing portion 132 moves away from the chuck ball 128. This allows the chuck ball 128 to move outward in the radial direction of the rotation axis AX. When the tip tool is inserted into the anvil hole 120 while the chuck ball 128 is in a movable state, the chuck ball 128 moves outward in the radial direction of the rotation axis AX so as to retract from the anvil hole 120. This allows the tip tool to be inserted into the anvil hole 120. When the chuck sleeve 122 moves backward due to the elastic force of the chuck spring 124 while the tool tip is placed in the anvil hole 120, the chuck ball fixing portion 132 comes into contact with the chuck ball 128, and the chuck ball 128 moves inward in the radial direction of the rotation axis AX. As a result, the tool tip is held by the chuck ball 128 and fixed to the anvil 17.

The reduction mechanism 12, spindle 13, and hammer 16 function as a power transmission mechanism that transmits the power generated by the motor 11 to the anvil 17. The anvil 17 functions as an output shaft that rotates based on the power generated by the motor 11.

The headlight 160 is disposed at the front of the lower part of the main body 4. The headlight 160 illuminates at least one of the work target of the power tool 1A and the tip tool held by the anvil 17.

<Handle section>
The handle portion 6 is held by a user of the power tool 1A. The handle portion 6 is a portion that is gripped by the hand of a user of the power tool 1A. The handle portion 6 is connected to a lower portion of the main body portion 4. The handle portion 6 includes a handle housing 2B that is connected to a lower portion of the motor housing 2A.

<Battery mounting section>
The battery mounting section 29 has a mounting surface 32 on which a battery 31 is mounted, and an operation surface 40 including an operation panel 44. The battery mounting section 29 is connected to the lower part of the handle section 6. The battery mounting section 29 includes a battery mounting housing 2C connected to the lower part of the handle housing 2B.

The battery 31 has a battery terminal. The battery terminal is disposed on the upper surface of the battery 31. The battery 31 has a raised portion 34 that protrudes upward at the front of the battery 31.

The mounting surface 32 includes the lower surface of the battery mounting section 29, which faces downward. The battery mounting section 29 has a mounting terminal. The mounting terminal is disposed on the mounting surface 32 of the battery mounting section 29.

The battery 31 is removably held in the battery mounting section 29. When mounting the battery 31 in the battery mounting section 29, the battery 31 is slid from the front to the rear of the battery mounting section 29 so that the top surface of the battery 31 faces the mounting surface 32. By sliding the battery 31, the rear of the protruding portion 34 comes into contact with the front of the battery mounting section 29. In addition, a battery claw 36 is provided on the top surface of the battery 31. The battery claw 36 protrudes from the top surface of the battery 31. The battery claw 36 can move upward by the elastic force of the elastic member. The battery claw 36 is inserted into a battery mounting recess 37 provided in the front of the battery mounting section 29. As a result, the battery 31 and the battery mounting section 29 are positioned, and the battery 31 is mounted in the battery mounting section 29.

When the battery 31 is attached to the battery attachment section 29, the top surface of the battery 31 faces the attachment surface 32. Furthermore, when the battery 31 is attached to the battery attachment section 29, the battery terminal and the attachment terminal are connected. This connects the battery 31 to a terminal 35 provided on the battery attachment section 29. The terminal 35 is connected to the control device 33.

When removing the battery 31 from the battery mounting section 29, the battery button 30 is operated. The battery button 30 is connected to an elastic member that can move the battery claw 36 upward. By operating the battery button 30, the battery claw 36 is disengaged from the battery mounting recess 37, and the battery 31 is released from the battery mounting section 29. After the battery 31 is released from the battery mounting section 29, the battery 31 is removed from the battery mounting section 29 by sliding the battery 31 forward.

The operation surface 40 is defined in the front part of the upper surface of the battery mounting section 29. The operation surface 40 is defined in the area on the upper surface of the battery mounting housing 2C, forward of the handle section 6. The operation panel 44 is provided on the operation surface 40.

Hook grooves 39 into which the hooks 38 are attached are provided on both the left and right sides of the battery mounting housing 2C. A strap 42 is attached to the rear of the battery mounting housing 2C.

<Forward/reverse switch>
The forward/reverse switch 28 is disposed at the lower end of the main body 4. The forward/reverse switch 28 is disposed at the middle of the main body 4 in the X-axis direction. The forward/reverse switch 28 is disposed so as to penetrate the motor housing 2A in the Y-axis direction. The forward/reverse switch 28 is an operating member that is operated by a user of the power tool 1A. By operating the forward/reverse switch 28, the rotation direction of the motor 11 is switched.

<Main switch>
The main switch 7 switches between starting and stopping the motor 11. The main switch 7 is located on the upper part of the handle portion 6. The main switch 7 is located on the handle portion 6 and has a trigger operating member 8 that is operated to start the motor 11, and a trigger signal output device 9 that outputs a trigger signal in response to the operation of the trigger operating member 8.

The trigger operating member 8 is disposed at the top of the handle portion 6. The trigger operating member 8 is disposed at the front of the handle portion 6 on the +X side. The handle housing 2B has an opening 3 in which the trigger operating member 8 is disposed. At least a portion of the trigger operating member 8 is disposed in the opening 3. The trigger operating member 8 protrudes forward beyond the front surface of the handle housing 2B.

The trigger operating member 8 is a block-shaped member. The trigger operating member 8 has a front end surface 8F facing forward. As shown in FIG. 2, in the Z-axis direction, the dimension W8 of the trigger operating member 8 is smaller than the dimension W6 of the handle portion 6. In the Z-axis direction, the trigger operating member 8 is disposed in the center of the handle portion 6. In the Z-axis direction, the center of the trigger operating member 8 coincides with the center of the handle portion 6.

The trigger signal output device 9 includes an electronic circuit that can output a trigger signal in response to the operation of the trigger operating member 8. The trigger signal is a command signal that starts the motor 11. The trigger signal output device 9 is disposed inside the handle housing 2B.

The trigger operating member 8 is operated by a user of the power tool 1A. When the trigger operating member 8 is operated, the trigger signal output device 9 housed inside the handle housing 2B outputs a trigger signal. When the trigger signal output device 9 outputs a trigger signal, the motor 11 starts. The power generated by the motor 11 is transmitted to the hammer 16 via the spindle 13. The hammer 16 rotates the anvil 17 that holds the tip tool.

A user of the power tool 1A can operate the trigger operating member 8 with his or her fingers while gripping the handle portion 6 with the hand. When the trigger operating member 8 is operated so as to move backward, a trigger signal is output from the trigger signal output device 9. As shown in FIG. 3, an elastic member 5 is disposed between the trigger operating member 8 and the trigger signal output device 9. When the operation of the trigger operating member 8 is released, the elastic force of the elastic member 5 causes the trigger operating member 8 to move forward. When the trigger operating member 8 moves forward, the output of the trigger signal from the trigger signal output device 9 stops. This stops the motor 11.

<Mode change switch>
The mode change switch 140 changes the rotation speed of the motor 11. The mode change switch 140 is disposed on the upper part of the handle portion 6.

Figure 4 is a cross-sectional view showing a portion of the power tool 1A according to this embodiment. As shown in Figures 1, 2, and 4, the mode change switch 140 is disposed on the handle portion 6 and has a mode operation member 142 that is operated to change the rotation speed of the motor 11, and a mode signal output device 144 that outputs a mode signal in response to the operation of the mode operation member 142.

The mode operation member 142 is disposed on the upper part of the handle portion 6. In the X-axis direction, the mode operation member 142 is disposed at a position different from the trigger operation member 8. The mode operation member 142 is disposed on the side of the handle portion 6. The mode operation member 142 is disposed on at least one of the right part of the handle portion 6 on the +Z side and the left part of the handle portion 6 on the -Z side. In this embodiment, the mode operation member 142 is disposed on the right part of the handle portion 6.

The handle housing 2B has an opening 146 in which the mode operating member 142 is disposed. At least a portion of the mode operating member 142 is disposed in the opening 146. At least a portion of the mode operating member 142 protrudes to the right beyond the right surface of the handle housing 2B.

The mode operation member 142 is a disk-shaped member. The mode operation member 142 includes a push button that is pressed by a user of the power tool 1A. The mode operation member 142 includes a main body member 1421 that can contact at least a part of the mode signal output device 144, a cover member 1422 that is positioned opposite the surface of the main body member 1421 and supported by the inner surface of the opening 146, and an elastic member 1423 that is connected to the main body member 1421 and supported by the inner surface of the opening 146.

The mode signal output device 144 includes an electronic circuit capable of outputting a mode signal by operating the mode operating member 142. The mode signal is a command signal that changes the rotation speed of the motor 11. The mode signal output device 144 is disposed inside the handle housing 2B. The mode signal output device 144 is supported on the right side of the trigger signal output device 9 via a support member 148.

As shown in FIG. 1, in the X-axis direction, the mode operating member 142 is disposed in the middle of the handle portion 6. In the Y-axis direction, the dimension H142 of the mode operating member 142 is smaller than the dimension H8 of the trigger operating member 8.

In the Y-axis direction, the distance Ha between the upper end 142A of the mode operating member 142 closest to the main body 4 and the rotation axis AX is longer than the distance Hb between the upper end 8A of the trigger operating member 8 closest to the main body 4 and the rotation axis AX. The upper end 142A of the mode operating member 142 is positioned lower than the upper end 8A of the trigger operating member 8.

In the Y-axis direction, the distance Hc between the lower end 142B of the mode operating member 142, which is the furthest from the main body 4, and the rotation axis AX is shorter than the distance Hd between the lower end 8B of the trigger operating member 8, which is the furthest from the main body 4, and the rotation axis AX. The lower end 142B of the mode operating member 142 is positioned higher than the lower end 8B of the trigger operating member 8.

In other words, in the Y-axis direction, the mode operating member 142 is disposed between the upper end 8A and the lower end 8B of the trigger operating member 8.

The mode operation member 142 is operated by the user of the power tool 1A. When the mode operation member 142 is operated, the mode signal output device 144 housed inside the handle housing 2B outputs a mode signal. When the mode signal output device 144 outputs a mode signal, the set value of the rotation speed of the motor 11 is changed.

A user of the power tool 1A can operate the mode operation member 142 with his or her fingers while holding the handle portion 6 in the hand. When the mode operation member 142 is operated so as to be pushed into the handle housing 2B, the main body member 1421 comes into contact with the mode signal output device 144, and a mode signal is output from the mode signal output device 144. When the operation of the mode operation member 142 is released, the elastic force of the elastic member 1423 causes the main body member 1421 to move away from the mode signal output device 144. When the main body member 1421 moves away from the mode signal output device 144, the output of the mode signal from the mode signal output device 144 stops.

<Control device>
The control device 33 controls the power tool 1A. As shown in FIG 3, the control device 33 includes a control circuit board and is disposed inside the battery mounting portion 29.

Figure 5 is a functional block diagram showing the power tool 1A according to this embodiment. The control device 33 has a processor such as a CPU (Central Processing Unit), a main memory including a non-volatile memory such as a ROM (Read Only Memory) and a volatile memory such as a RAM (Random Access Memory), and an interface including an input/output circuit.

The control device 33 is connected to the terminal 35, the trigger signal output device 9, the mode signal output device 144, the operation panel 44, and the motor 11. The battery 31 is connected to the control device 33 via the terminal 35.

The operation panel 44 has an impact force change button 44A that is operated to change the impact force of the hammer 16, and a display device 44B. The display device 44B includes a mode display section that displays the rotation speed of the motor 11, an impact force display section that displays the impact force of the hammer 16, and a battery remaining charge display section that displays the remaining charge of the battery 31.

When the mode operating member 142 is operated, the control device 33 sequentially switches the set value of the rotation speed of the motor 11 between four levels, "maximum," "high," "medium," and "low," based on the mode signal output from the mode signal output device 144 each time the mode operating member 142 is operated. In the initial state where the battery 31 is attached to the battery attachment section 29, the control device 33 sets the rotation speed of the motor 11 to "maximum."

When the rotation speed of the motor 11 is set to "maximum" and the mode operating member 142 is operated once, the control device 33 changes the rotation speed of the motor 11 to "high."

When the rotation speed of the motor 11 is set to "high" and the mode operating member 142 is operated once, the control device 33 changes the rotation speed of the motor 11 to "medium."

When the rotation speed of the motor 11 is set to "medium" and the mode operating member 142 is operated once, the control device 33 changes the rotation speed of the motor 11 to "low."

When the rotation speed of the motor 11 is set to "low" and the mode operating member 142 is operated once, the control device 33 changes the rotation speed of the motor 11 to "highest."

The control device 33 displays the set rotation speed of the motor 11 on the mode display section of the display device 44B.

When the trigger operating member 8 is operated, the control device 33 outputs a control signal to the motor 11 to operate the motor 11 with the rotation speed set by the mode change switch 140 as the upper limit based on the trigger signal output from the trigger signal output device 9.

The control device 33 may adjust the rotation speed of the motor 11 based on the amount of operation of the trigger operating member 8, with the rotation speed set by the mode change switch 140 as the upper limit. For example, when the amount of operation of the trigger operating member 8 is small, the motor 11 may be rotated at a low speed, and when the amount of operation of the trigger operating member 8 is large, the motor 11 may be rotated at a high speed.

When the impact force switching button 44A on the operation panel 44 is operated, the control device 33 sequentially switches the impact force setting value between four levels: "strongest," "strong," "medium," and "weak" each time the impact force switching button 44A is operated. The control device 33 displays the set impact force on the impact force display section of the display device 44B.

<Usage example>
Fig. 6 is a perspective view of the power tool 1A according to this embodiment, as viewed from the rear. As shown in Fig. 6, a user can hold the handle portion 6 with, for example, his/her right hand. While holding the handle portion 6 with his/her right hand, the user can operate the trigger operating member 8 with the index finger of his/her right hand.

The mode operation member 142 is located on the upper right side of the handle portion 6. This allows the user to operate the mode operation member 142 with the thumb of the right hand while holding the handle portion 6 in the right hand.

The user operates the mode operating member 142 with his/her thumb to set the rotation speed of the motor 11. The user can change the rotation speed of the motor 11 by operating the mode operating member 142 with his/her thumb while checking the rotation speed of the motor 11 to be set by looking at the mode display portion of the display device 44B.

After the rotation speed of the motor 11 has been set, the user operates the trigger operating member 8 with the index finger. This starts the motor 11. The motor 11 rotates at a rotation speed up to the upper limit set by the mode change switch 140.

The rotation of the motor 11 also rotates the fan 10. As the fan 10 rotates, air outside the motor housing 2A flows into the motor housing 2A through the intake port 25, and air inside the motor housing 2A is exhausted through the exhaust port 24. This cools the motor 11.

The rotational force generated by the motor 11 is decelerated by the reduction mechanism 12 and then transmitted to the spindle 13 via the reduction mechanism 12, causing the spindle 13 to rotate. The rotational force of the spindle 13 is transmitted to the anvil 17 via the hammer 16. This causes the tip tool held by the anvil 17 to rotate, allowing the user to perform work with the power tool 1A.

＜Effects＞
As described above, according to this embodiment, the mode operation member 142 is disposed on the handle portion 6. This allows the user to change the rotation speed of the motor 11 by operating the mode operation member 142 with a finger while gripping the handle portion 6 with a hand. In this embodiment, for example, while gripping the handle portion 6 with the right hand, the user can operate both the mode operation member 142 and the trigger operation member 8 without using the left hand. This prevents deterioration in operability of the power tool 1A.

In the X-axis direction, the mode operation member 142 is disposed at a different position from the trigger operation member 8. This allows the user to, for example, grip the handle portion 6 with the right hand, operate the trigger operation member 8 with the index finger of the right hand, and operate the mode operation member 142 with the thumb of the right hand.

In the Y-axis direction, the distance Ha between the upper end 142A of the mode operating member 142 and the rotation axis AX is longer than the distance Hb between the upper end 8A of the trigger operating member 8 and the rotation axis AX. This allows the user to smoothly operate the mode operating member 142 with their thumb while gripping the handle portion 6 with their hand.

In the Y-axis direction, the mode operation member 142 is disposed between the upper end 8A and the lower end 8B of the trigger operation member 8. This prevents the mode operation member 142 from being erroneously operated. If the mode operation member 142 is disposed below the trigger operation member 8, there is a high possibility that at least a part of the hand gripping the handle portion 6 will touch the mode operation member 142. As a result, there is a possibility that the mode operation member 142 will be operated against the user's will. In this embodiment, in the Y-axis direction, the mode operation member 142 is disposed between the upper end 8A and the lower end 8B of the trigger operation member 8. This prevents the hand gripping the handle portion 6 from touching the mode operation member 142. This prevents the mode operation member 142 from being erroneously operated.

The mode operation member 142 is located on the right side of the handle portion 6. This allows the user to operate the mode operation member 142 with the thumb of the right hand while holding the handle portion 6 with the right hand.

<Modification>
Fig. 7 is a perspective view of the power tool 1A according to this embodiment, as viewed from the front. As shown in Fig. 7, the mode operation member 142 may be disposed on the left side of the handle portion 6. In the Y-axis direction, the mode operation member 142 is disposed between the upper end portion 8A and the lower end portion 8B of the trigger operation member 8. This allows the user to operate the mode operation member 142 with the thumb of the left hand and operate the trigger operation member 8 with the index finger of the left hand while holding the handle portion 6 with the left hand, without using the right hand.

Figure 8 is a rear perspective view of the power tool 1A according to this embodiment. As shown in Figure 8, the mode operation member 142 may be located at the rear of the handle portion 6 on the -X side. In the Y-axis direction, the mode operation member 142 is located between the upper end portion 8A and the lower end portion 8B of the trigger operation member 8. While holding the handle portion 6 with one hand, the user can operate the mode operation member 142 with his thumb and the trigger operation member 8 with his index finger.

9 is a side view of the electric power tool 1A according to this embodiment, as viewed from the right. As shown in FIG. 9, in the Y-axis direction, the distance He between the lower end 142B of the mode operating member 142 closest to the battery mounting portion 29 and the mounting surface 32 of the battery mounting portion 29 may be shorter than the distance Hf between the lower end 8B of the trigger operating member 8 closest to the battery mounting portion 29 and the mounting surface 32 of the battery mounting portion 29. In other words, the lower end 142B of the mode operating member 142 may be disposed lower than the lower end 8B of the trigger operating member 8. In other words, at least a part of the mode operating member 142 may be disposed lower than the lower end 8B of the trigger operating member 8 in the Y-axis direction.

Figure 9 shows an example in which the upper end 142A of the mode operating member 142 is positioned on the +Y side of the lower end 8B of the trigger operating member 8. Note that the upper end 142A of the mode operating member 142 may be positioned on the +Y side of the upper end 8A of the trigger operating member 8, and the lower end 142B of the mode operating member 142 may be positioned on the -Y side of the lower end 8B of the trigger operating member 8. In other words, in the Y-axis direction, the dimension H142 of the mode operating member 142 may be greater than the dimension H8 of the trigger operating member 8.

Figure 9 shows an example in which the mode operation member 142 is provided on the right side of the handle portion 6. The mode operation member 142, at least a portion of which is located below the lower end portion 8B of the trigger operation member 8 in the Y-axis direction, may be provided on the left side of the handle portion 6 or on the rear side of the handle portion 6.

Figure 10 is a rear perspective view of the power tool 1A according to this embodiment. Figure 10 shows an example in which the mode operating member 142 and the trigger operating member 8 are positioned at different positions in the Y-axis direction.

As shown in FIG. 10, the mode operating member 142 may be disposed below the trigger operating member 8 at the rear of the handle portion 6. That is, in the Y-axis direction, both the upper end 142A and the lower end 142B of the mode operating member 142 may be disposed below the lower end 8B of the trigger operating member 8. In other words, in the Y-axis direction, the distance between the mode operating member 142 and the rotation axis AX may be longer than the distance between the trigger operating member 8 and the rotation axis AX.

As shown by the dotted lines in FIG. 10, both the upper end 142A and the lower end 142B of the mode operating member 142 may be positioned lower than the lower end 8B of the trigger operating member 8 on at least one of the right and left parts of the handle portion 6.

Figure 11 is a front perspective view of the power tool 1A according to this embodiment. As with Figure 10, Figure 11 also shows an example in which the mode operating member 142 and the trigger operating member 8 are positioned at different positions in the Y-axis direction.

As shown in FIG. 11, the mode operation member 142 may be disposed below the trigger operation member 8 at the front of the handle portion 6. Also, in the Y-axis direction, the mode operation member 142 may be disposed below the center of the handle portion 6. FIG. 11 shows an example in which the mode operation member 142 is disposed at the lower end of the handle portion 6.

In the Y-axis direction, the distance He between the lower end 142B of the mode operating member 142 closest to the battery mounting section 29 and the mounting surface 32 of the battery mounting section 29 is shorter than the distance Hf between the lower end 8B of the trigger operating member 8 closest to the battery mounting section 29 and the mounting surface 32 of the battery mounting section 29.

In the Y-axis direction, the distance Hg between the upper end 142A of the mode operating member 142 closest to the main body 4 and the mounting surface 32 of the battery mounting section 29 is shorter than the distance Hh between the center of the handle section 6 and the mounting surface 32 of the battery mounting section 29.

The mode operation member 142 is located at the lower end of the handle portion 6, so that the user can grip the handle portion 6 with his or her right hand, operate the trigger operation member 8 with the index finger of the right hand, and operate the mode operation member 142 with the little finger of the right hand.

As shown by the dotted line in FIG. 11, the mode operation member 142 may be located at the lower end of the left part of the handle portion 6. Even in this case, the user can operate the mode operation member 142 with the little finger of the right hand while holding the handle portion 6 with the right hand.

The mode operation member 142 may be located at the lower end of the right part of the handle portion 6. In this case, the user can operate the mode operation member 142 with the little finger of the left hand while holding the handle portion 6 with the left hand.

The mode operation member 142 may also be located at the lower end of the rear of the handle portion 6.

In the above embodiment, the upper end 142A of the mode operating member 142 may be disposed on the +Y side of the upper end 8A of the trigger operating member 8. In addition, when the upper end 142A of the mode operating member 142 is disposed on the +Y side of the upper end 8A of the trigger operating member 8, the lower end 142B of the mode operating member 142 may be disposed on the +Y side of the lower end 8B of the trigger operating member 8, or may be disposed on the -Y side of the lower end 8B of the trigger operating member 8.

[Second embodiment]
A second embodiment will be described below. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof will be simplified or omitted.

In the above embodiment, an example was described in which the mode operation member 142 is provided on the handle portion 6. In the present embodiment, an example is described in which the mode operation member 142 is provided on the battery mounting portion 29.

Figure 12 is a front perspective view of the power tool 1B according to this embodiment. As shown in Figure 12, the power tool 1B includes a main body 4, a handle 6 extending in the Y-axis direction, and a battery attachment section 29 connected to the -Y end of the handle 6.

As in the above embodiment, the trigger operating member 8 is located at the front of the handle portion 6.

The battery mounting section 29 has a mounting surface 32 on which the battery 31 is mounted, and an operation surface 40 including an operation panel 44. The mounting surface 32 includes at least a portion of the bottom surface of the battery mounting section 29 facing the -Y side. The operation surface 40 includes at least a portion of the top surface of the battery mounting section 29 facing the +Y side. In this embodiment, the operation surface 40 includes a portion of the top surface of the battery mounting section 29 that is defined forward of the handle section 6. In other words, the operation surface 40 includes the area of the top surface of the battery mounting section 29 below the trigger operating member 8.

The mode operation member 142 is disposed on a defined surface 41 of the surface of the battery mounting section 29 that is different from the mounting surface 32 and the operation surface 40. The defined surface 41 of the battery mounting section 29 that is different from the mounting surface 32 and the operation surface 40 includes a surface 41A on the left side and a surface 41B on the right side of the battery mounting section 29. In the example shown in FIG. 12, the mode operation member 142 is disposed on the surface 41A of the battery mounting section 29.

The mode operation member 142 is located on the surface 41A of the battery mounting section 29, so that the user can operate the trigger operation member 8 with the index finger of the right hand while holding the handle section 6 with the right hand, and operate the mode operation member 142 with the little finger of the right hand.

Figure 13 is a perspective view of the power tool 1B according to this embodiment, as seen from the rear. As shown in Figure 13, the mode operation member 142 may be disposed on the surface 41B of the right part of the battery mounting section 29. This allows the user to operate the trigger operation member 8 with the index finger of the left hand and the mode operation member 142 with the little finger of the left hand while holding the handle section 6 with the left hand.

The surface 41 on which the mode operating member 142 is disposed may be the rear surface 41C of the battery mounting portion 29, which is located behind the handle portion 6. As shown by the dotted line in FIG. 13, the mode operating member 142 may be disposed on the surface 41C.

[Third embodiment]
A third embodiment will be described below. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof will be simplified or omitted.

In this embodiment, an example in which the mode operation member 142 is provided on the main body 4 will be described.

Figure 14 is a perspective view of the power tool 1C according to this embodiment, as seen from the rear. The mode operation member 142 is arranged on the side of the main body 4, which is arranged around the rotation axis AX. The mode operation member 142 is arranged on at least one of the +X and -X sides of the center in the X-axis direction on the side of the main body 4. Figure 14 shows an example in which the mode operation member 142 is arranged on each of the front and rear parts of the side of the main body 4. In the following description, the mode operation member 142 arranged on the front part of the side will be appropriately referred to as mode operation member 142F, and the mode operation member 142 arranged on the rear part of the side will be appropriately referred to as mode operation member 142R.

In the Y-axis direction, the mode operation member 142 (142F, 142R) is disposed on the -Y side of the rotation axis AX. In other words, the mode operation member 142 is provided at the bottom of the main body 4.

The mode operation member 142F is arranged, for example, around the hammer case 21. At least a portion of the mode operation member 142F is arranged on the +X side of the front end surface 8F of the trigger operation member 8, which is on the +X side.

The mode operation member 142R is disposed between the intake port 25 and the exhaust port 24 in the X-axis direction. The mode operation member 142R is disposed, for example, around the motor 11.

With the user gripping the handle portion 6 with his/her right hand, he/she can, for example, operate the trigger operation member 8 with the middle finger of his/her right hand, operate the mode operation member 142F with the index finger of his/her right hand, and operate the mode operation member 142R with the thumb of his/her right hand. The mode operation members 142 (142F, 142R) are positioned below the rotation axis AX, so that the user can reach the mode operation members 142 (142F, 142R) with his/her fingers while gripping the handle with one hand.

When two mode operating members 142, mode operating member 142F and mode operating member 142R, are arranged, the control device 33 may change the rotation speed of the motor 11 when both mode operating member 142F and mode operating member 142R are operated simultaneously by the user's index finger and thumb.

In the example shown in FIG. 14, the mode operation members 142 (142F, 142R) are provided on the right side surface of the main body 4. The mode operation members 142 (142F, 142R) may be provided on the left side surface of the main body 4.

The mode operating member 142F does not have to be positioned on the +X side of the front end surface 8F of the trigger operating member 8.

In addition, either the mode operation member 142F or the mode operation member 142R may be disposed on the side of the main body 4.

Figure 15 is a front perspective view of the power tool 1C according to this embodiment. The mode operation member 142 is disposed on the top end surface of the main body 4, farther from the handle portion 6 in the Y-axis direction than the rotation axis AX. The mode operation member 142 is also disposed on the top end surface of the main body 4, on the +X side of the center in the X-axis direction. In the Z-axis direction, at least a portion of the mode operation member 142 coincides with the rotation axis AX. Note that in the Z-axis direction, the mode operation member 142 does not have to coincide with the rotation axis AX.

The mode operation member 142 is disposed around the hammer case 21. At least a portion of the mode operation member 142 is disposed on the +X side of the front end face 8F of the trigger operation member 8, which is the +X side closest to the front end face 8F.

While holding the handle portion 6 with one hand, the user can operate the trigger operating member 8 with, for example, his/her middle finger and the mode operating member 142 with his/her index finger.

The mode operating member 142 does not have to be positioned on the +X side of the front end surface 8F of the trigger operating member 8.

[Fourth embodiment]
A fourth embodiment will be described below. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof will be simplified or omitted.

In this embodiment, the power tool 1D is a driver drill.

Figure 16 is a rear perspective view of the electric power tool 1D according to this embodiment. The electric power tool 1D has a main body 4 including a motor 11, a handle 6 connected to the lower part of the main body 4 and extending in the -Y direction, and a battery mounting part 29 connected to the lower end of the handle 6 and in which a battery 31 is mounted.

A trigger operating member 8 is disposed at the front of the handle portion 6. A forward/reverse switch 28 is disposed at the lower end of the main body portion 4. An operation surface 40 including an operation panel 44 is defined on a portion of the upper surface of the battery mounting portion 29. The main body portion 4 includes a drill chuck 18 disposed at the front end, and a tightening force switching ring 19. The drill chuck 18 is capable of holding a tool tip and rotating around the rotation axis AX. The rotation axis AX is parallel to the X-axis.

A mode operation member 142 is disposed on at least a portion of the surface of the power tool 1D. The mode operation member 142 is disposed on the handle portion 6. In the X-axis direction, the mode operation member 142 is disposed at a position different from the trigger operation member 8. As shown in FIG. 16, the mode operation member 142 may be disposed on the right side of the handle portion 6. In the Y-axis direction, the mode operation member 142 may be disposed between the upper end 8A and the lower end 8B of the trigger operation member 8. The mode operation member 142 may be disposed on the left side of the handle portion 6.

As shown by the dotted line in FIG. 16, the mode operating member 142 may be disposed at the rear of the handle portion 6. At least a portion of the mode operating member 142 may be disposed below the trigger operating member 8 in the Y-axis direction.

The mode operating member 142 may be located at the lower end of at least one of the right, left, and rear portions of the handle portion 6.

Figure 17 is a perspective view of the power tool 1D according to this embodiment, as viewed from the front. As shown in Figure 17, the mode operation member 142 may be disposed in the front of the handle portion 6. The mode operation member 142 may be disposed in the front of the handle portion 6, at the lower end of the handle portion 6. As shown by the dotted lines in Figure 17, the mode operation member 142 may be disposed on a defined surface 41 of the battery mounting portion 29 that is different from the mounting surface 32 and the operating surface 40.

Although not shown in the figures, the mode operation member 142 may be disposed on at least a portion of the surface of the main body 4, similar to the above-described embodiment.

[Fifth embodiment]
A fifth embodiment will be described below. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof will be simplified or omitted.

In this embodiment, the power tool 1E is a screwdriver.

Figure 18 is a rear perspective view of the electric power tool 1E according to this embodiment. The electric power tool 1E includes a main body 4 including a motor, a handle 6 connected to the main body 4 and at least a portion of which is disposed at a different position from the main body 4 in the X-axis direction parallel to the rotation axis AX of the motor, a battery mounting section 29 connected to each of the main body 4 and the handle 6 and having a mounting surface 32 on which a battery 31 is mounted and an operation surface 40 including an operation panel 44, and a trigger operating member 8 disposed on the handle 6 and used to start the motor.

The main body 4 extends in the X-axis direction. The handle 6 extends in the Y-axis direction. The main body 4 is disposed forward of the handle 6. The rear of the main body 4 is connected to the upper end of the handle 6 via the first connection part 45. The lower part of the main body 4 is connected to the battery mounting part 29 via the second connection part 46. The lower end of the handle 6 is connected to the battery mounting part 29. A loop is formed by at least a part of the main body 4, the first connection part 45, the handle 6, at least a part of the battery mounting part 29, and the second connection part 46.

The main body 4 has a lock ring 47 and a drill chuck 18. The drill chuck 18 holds the tool tip and can rotate around the rotation axis AX.

The handle portion 6 has a trigger operating member 8 and a forward/reverse switch 28. The trigger operating member 8 is located at the top of the front portion of the handle portion 6.

The mode operation member 142 is disposed on at least a portion of the prescribed surface 41 of the main body 4, the handle 6, and the battery mounting section 29. The prescribed surface 41 is a surface of the battery mounting section 29 that is different from the mounting surface 32 and the operation surface 40.

In the example shown in FIG. 18, the mode operation member 142 is disposed on the upper surface of the handle portion 6. This allows the user to operate the trigger operation member 8 with the index finger and the mode operation member 142 with the thumb while holding the handle portion 6 with one hand.

As shown by the dotted line in FIG. 18, the mode operation member 142 may be located at the upper part of the rear surface of the handle portion 6. Even in this case, the user can operate the trigger operation member 8 with the index finger and the mode operation member 142 with the thumb while holding the handle portion 6 with one hand.

As shown by the dotted line in FIG. 18, the mode operation member 142 may be disposed on the prescribed surface 41 to the right of the handle portion 6. This allows the user to operate the trigger operation member 8 with the index finger of the right hand while gripping the handle portion 6 with the right hand, and to operate the mode operation member 142 with the little finger of the right hand. The mode operation member 142 may be disposed on the prescribed surface 41 to the left of the handle portion 6. This allows the user to operate the mode operation member 142 with the little finger of the left hand while gripping the handle portion 6 with the left hand.

Figure 19 is a front perspective view of the power tool 1E according to this embodiment. As shown in Figure 19, the mode operation member 142 may be provided at the front of the handle portion 6. The mode operation member 142 is disposed below the trigger operation member 8. This allows the user to operate the trigger operation member 8 with the index finger and the mode operation member 142 with the middle finger while holding the handle portion 6 with one hand.

The mode operation member 142 may be disposed on at least a portion of the main body 4.

Sixth Embodiment
A sixth embodiment will be described below. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof will be simplified or omitted.

In this embodiment, the power tool 1F is an angle impact driver.

Figure 20 is a rear perspective view of the electric power tool 1F according to this embodiment. The electric power tool 1F includes a main body 4 having a motor 11 and an anvil 17, a handle 6 connected to the main body 4, a battery mounting section 29 to which a battery 31 is attached, and a trigger operating member 8 disposed on the handle 6 and used to start the motor 11.

The motor 11 rotates around a rotation axis AX. The rotation axis AX is parallel to the X-axis. The main body 4 extends in the X-axis direction. The anvil 17 holds the tool tip and rotates around a rotation axis BX that intersects with the rotation axis AX of the motor 11. A power transmission mechanism including a bevel gear is disposed between the motor 11 and the anvil 17. The rotation axis BX of the anvil 17 is parallel to the Y-axis.

The handle portion 6 is connected to the rear end of the main body portion 4. The handle portion 6 extends in the X-axis direction. The trigger operating member 8 is disposed at the bottom of the handle portion 6. The battery attachment portion 29 is connected to the rear end of the handle portion 6.

The mode operation member 142 is disposed on at least a portion of the main body portion 4, the handle portion 6, and the battery mounting portion 29.

As shown in FIG. 20, the mode operation member 142 may be disposed on the upper surface of the handle portion 6. This allows the user to operate the mode operation member 142 with his or her thumb while holding the handle portion 6 and the trigger operation member 8 with one hand.

Figure 21 is a front perspective view of the power tool 1F according to this embodiment. As shown in Figure 21, the mode operation member 142 may be provided on the left side of the handle portion 6. This allows the user to operate the mode operation member 142 with the thumb of the right hand while holding the handle portion 6 and the trigger operation member 8 with the right hand.

The mode operation member 142 may be provided on the right side of the handle portion 6. This allows the user to operate the mode operation member 142 with the thumb of the left hand while holding the handle portion 6 and the trigger operation member 8 with the left hand.

Also, as shown by the dotted line in FIG. 21, the mode operation member 142 may be disposed in the battery mounting section 29. This allows the user to operate the mode operation member 142 with his/her little finger while holding the handle section 6 and the trigger operation member 8 with one hand.

The mode operation member 142 may be disposed on at least a portion of the main body 4.

[Seventh embodiment]
A seventh embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof will be simplified or omitted.

In the above embodiment, an example was described in which the mode operation member 142 is a push button. The rotation speed of the motor 11 may be changed by moving at least a portion of the mode operation member in a direction parallel to the surface of the housing 2.

Figure 22 is a rear perspective view of the power tool 1G according to this embodiment. In this embodiment, the power tool 1G is an impact driver.

As shown in FIG. 22, the power tool 1G includes a housing 2 that defines the surfaces of a main body 4 including a motor 11, a handle 6 connected to the main body 4, and a battery mounting section 29 to which a battery 31 is attached, a trigger operating member 8 disposed on the handle 6 for starting the motor 11, and a mode operating member 150 for changing the rotation speed of the motor 11.

The housing 2 includes a motor housing 2A, a rear housing 20, a front housing 26, a handle housing 2B, and a battery mounting housing 2C.

The mode operation member 150 is disposed on at least a portion of the main body 4, the handle 6, and the battery mounting portion 29, and at least a portion of the mode operation member 150 moves in a direction parallel to the surface of the housing 2 to change the rotational speed of the motor 11.

22, the mode operation member 150 includes a slide member disposed on the surface of the rear of the main body 4. The mode operation member 150 is slidable in a direction parallel to the surface of the rear housing 20. In the example shown in FIG. 22, the surface of the rear housing 20 is substantially parallel to the YZ plane. The mode operation member 150 is movable in the Y-axis direction.

Figure 23 is a diagram showing the mode operation member 150 according to this embodiment. As shown in Figures 22 and 23, a guide groove 150G that guides the mode operation member 150 is formed in the rear housing 20. The guide groove 150G extends in the Y-axis direction.

The mode operation member 150 moves in the Y-axis direction while being guided by the guide groove 150G. The mode operation member 150 can move in both the +Y direction, which is a first operation direction, and the -Y direction, which is a second operation direction different from the first operation direction.

The mode operation member 150 can be moved to each of a number of positions defined in the Y-axis direction. The rotation speed of the motor 11 is changed by moving the mode operation member 150.

The mode operating member 150 can be moved to four positions defined in the Y-axis direction. When the mode operating member 150 is moved to the first position, which is the furthest on the +Y side, the rotation speed of the motor 11 is set to "maximum". When the mode operating member 150 is moved to the second position on the +Y side after the first position, the rotation speed of the motor 11 is set to "high", which is lower than "maximum". When the mode operating member 150 is moved to the third position on the +Y side after the second position, the rotation speed of the motor 11 is set to "medium", which is lower than "high". When the mode operating member 150 is moved to the fourth position, which is the furthest on the -Y side among the four positions, the rotation speed of the motor 11 is set to "low", which is lower than "medium".

For example, when the mode operating member 150 located at the third position is operated in the +Y direction, the rotation speed of the motor 11 is changed from "medium" to "high", and when the mode operating member 150 located at the third position is operated in the -Y direction, the rotation speed of the motor 11 is changed from "medium" to "low". Similarly, when the mode operating member 150 located at the second position is operated in the +Y direction, the rotation speed of the motor 11 is changed from "high" to "maximum", and when the mode operating member 150 located at the second position is operated in the -Y direction, the rotation speed of the motor 11 is changed from "high" to "medium".

The user can operate the mode operation member 150, for example, with the thumb while holding the handle portion 6 with one hand. The mode operation member 150 slides in a direction parallel to the surface of the housing 2, allowing the user to operate the mode operation member 150 with good operability.

In addition, when the mode operating member 150 is operated in a first operating direction, the rotation speed of the motor 11 becomes high, and when the mode operating member 150 is operated in a second operating direction, the rotation speed of the motor 11 becomes low. This allows the motor 11 to be set to any desired rotation speed with fewer operations compared to the push button method.

The mode operation member 150 can be placed at any position on the power tool 1G. If the user can operate the mode operation member 150 with a finger while holding the handle portion 6 with one hand, the mode operation member 150 can be placed at any position on the surface of the power tool 1G.

The direction of movement of the mode operation member 150 can be set arbitrarily based on the position where the mode operation member 150 is placed. For example, by placing the mode operation member 150 that slides in the X-axis direction at the top end of the right part of the handle unit 6 or on the right part of the main body unit 4, the user can slide the mode operation member 150 in the X-axis direction with good operability, for example, using the thumb of the right hand while holding the handle unit 6 with the right hand. Note that the mode operation member 150 that can slide in at least one of the X-axis direction and the Z-axis direction may be placed on the top surface of the main body unit 4.

A mode operation member 150 that is slidable in at least one of the X-axis direction, Y-axis direction, and Z-axis direction may be disposed at the lower end of the handle portion 6. This allows the user to slide the mode operation member 150, for example, with the little finger while holding the handle portion 6 with one hand.

A mode operation member 150 that can slide in at least one of the X-axis direction, Y-axis direction, and Z-axis direction may be disposed in the battery mounting section 29. This allows the user to slide the mode operation member 150, for example, with the little finger, while holding the handle section 6 with one hand.

Note that the mode operation member that can move in a direction parallel to the surface of the housing 2 is not limited to a slide member.

Figure 24 is a diagram showing the mode operation member 151 according to this embodiment. Figure 24 shows an example in which the mode operation member 151 is a dial member that rotates in a plane parallel to the surface of the housing 2. The mode operation member 151 is supported by the housing 2 so as to be rotatable about a rotation axis CX that is perpendicular to the surface of the housing 2. By rotating about the rotation axis CX, at least a portion of the mode operation member 151 moves in a direction parallel to the surface of the housing 2.

The mode operation member 151 can rotate in one direction, which is a first operation direction, about the rotation axis CX, and in the opposite direction, which is a second operation direction different from the first operation direction.

The mode operation member 151 can rotate to each of a number of positions defined around the rotation axis CX. By rotating the mode operation member 151, the rotation speed of the motor 11 is changed.

The mode operating member 151 can be moved to each of four positions defined around the rotation axis CX. By moving the mode operating member 151 to the fifth position around the rotation axis CX, the rotation speed of the motor 11 is set to "maximum". By moving the mode operating member 151 to the sixth position around the rotation axis CX, which is adjacent to one side of the fifth position, the rotation speed of the motor 11 is set to "high". By moving the mode operating member 151 to the seventh position around the rotation axis CX, which is adjacent to one side of the sixth position, the rotation speed of the motor 11 is set to "medium". By moving the mode operating member 151 to the eighth position around the rotation axis CX, which is adjacent to one side of the seventh position, the rotation speed of the motor 11 is set to "low".

Furthermore, for example, by operating the mode operation member 151 located at the seventh position in one direction, the rotation speed of the motor 11 is changed from "medium" to "low", and by operating the mode operation member 151 located at the seventh position in the opposite direction, the rotation speed of the motor 11 is changed from "medium" to "high". Similarly, for example, by operating the mode operation member 151 located at the sixth position in one direction, the rotation speed of the motor 11 is changed from "high" to "medium", and by operating the mode operation member 151 located at the sixth position in the opposite direction, the rotation speed of the motor 11 is changed from "high" to "maximum".

The user can operate the mode operation member 151 with his/her fingers while holding the handle portion 6 with one hand. The mode operation member 151 rotates in a plane parallel to the surface of the housing 2, allowing the user to operate the mode operation member 151 with good operability.

When the mode operation member 151 is operated in the first operating direction, the rotation speed of the motor 11 becomes slow, and when the mode operation member 150 is operated in the second operating direction, the rotation speed of the motor 11 becomes high. This allows the motor 11 to be set to any rotation speed with a small number of operations.

The mode operation member 151 can be placed at any position on the power tool 1G. If a user can operate the mode operation member 151 with a finger while holding the handle portion 6 in one hand, the mode operation member 151 can be placed at any position on the surface of the power tool 1G. The mode operation member 151 may be placed on at least a portion of the surface of the main body portion 4, at least a portion of the surface of the handle portion 6, or at least a portion of the surface of the battery mounting portion 29.

Figure 25 is a diagram showing the mode operation member 152 according to this embodiment. Figure 25 shows an example in which the mode operation member 152 is a lever member having a tip portion that moves in a direction parallel to the surface of the housing 2. The mode operation member 152 has a base end portion that is supported by the housing 2, and tilts around the base end portion. As the mode operation member 152 tilts, the tip portion of the mode operation member 152 moves in a direction parallel to the surface of the housing 2.

The mode operating member 152 can be tilted in one direction, which is a first operating direction centered on the base end, and in the opposite direction, which is a second operating direction different from the first operating direction.

The tip of the mode operation member 152 can be rotated to each of a number of positions. The rotation speed of the motor 11 is changed by tilting the mode operation member 152 and moving the tip of the mode operation member 152.

The mode operating member 152 can be moved to each of four positions. By moving the mode operating member 152 to the ninth position, the rotation speed of the motor 11 is set to "highest". By moving the mode operating member 152 to the tenth position, which is adjacent to one side of the ninth position, the rotation speed of the motor 11 is set to "high". By moving the mode operating member 152 to the eleventh position, which is adjacent to one side of the tenth position, the rotation speed of the motor 11 is set to "medium". By moving the mode operating member 152 to the twelfth position, which is adjacent to one side of the eleventh position, the rotation speed of the motor 11 is set to "low".

For example, when the mode operating member 152 located at the 11th position is operated in one direction, the rotation speed of the motor 11 is changed from "medium" to "low", and when the mode operating member 152 located at the 11th position is operated in the opposite direction, the rotation speed of the motor 11 is changed from "medium" to "high". Similarly, when the mode operating member 152 located at the 10th position is operated in one direction, the rotation speed of the motor 11 is changed from "high" to "medium", and when the mode operating member 152 located at the 10th position is operated in the opposite direction, the rotation speed of the motor 11 is changed from "high" to "highest".

The user can operate the mode operation member 152 with a finger while holding the handle portion 6 with one hand. The mode operation member 152 moves in a direction parallel to the surface of the housing 2, allowing the user to operate the mode operation member 152 with good operability.

When the mode operating member 152 is operated in a first operating direction, the rotation speed of the motor 11 becomes slow, and when the mode operating member 152 is operated in a second operating direction, the rotation speed of the motor 11 becomes high. This allows the motor 11 to be set to any rotation speed with a small number of operations.

The mode operation member 152 can be placed at any position on the power tool 1G. As long as the user can operate the mode operation member 152 with a finger while holding the handle portion 6 with one hand, the mode operation member 152 can be placed at any position on the surface of the power tool 1G. The mode operation member 152 may be placed on at least a portion of the surface of the main body portion 4, at least a portion of the surface of the handle portion 6, or at least a portion of the surface of the battery mounting portion 29.

In this embodiment, the power tool 1G is an impact driver. The power tool 1G may be at least one of a driver drill, a screwdriver, and an angle impact driver, as described in the above embodiments.

The power tool 1 is not limited to a power tool for tightening screws. The power tool 1 may be at least one of a circular saw, a reciprocating saw, a grinder, a hammer drill, a chain saw, a grass cutter, and a hedge trimmer. In the case of a hammer drill and a reciprocating saw, the output unit that detachably holds and drives the tip tool moves the tip tool back and forth.

In the above embodiment, the power source for the power tool 1 does not have to be the battery 31. The power tool 1 may be operated based on power supplied from an AC (Alternating Current) outlet.

1A, 1B, 1C... power tool (impact driver), 1D... power tool (driver drill), 1E... power tool (screwdriver), 1F... power tool (angle impact driver), 1G... power tool, 2... housing, 2A... motor housing, 2B... handle housing, 2C... battery mounting housing, 3... opening, 4... main body, 5... elastic member, 6... handle, 7... main switch, 8... trigger operating member, 8A... upper end (one end), 8B... lower end (other end), 8F... front end surface, 9... trigger signal output device, 10... fan, 11... motor, 12... reduction mechanism, 13... spindle, 14... spring, 16... hammer, 17... anvil, 18... drill chuck, 19... tightening force switching ring, 20... rear housing, 21... hammer Case, 24...exhaust port, 25...intake port, 26...front housing, 27...bumper, 28...forward/reverse switch, 29...battery mounting section, 30...battery button, 31...battery, 32...mounting surface, 33...control device, 34...raised portion, 35...terminal, 36...battery claw, 37...battery mounting recess, 38...hook, 39...groove for hook, 40...operation surface, 41...regulating surface, 41A...surface, 41B...surface, 42...strap, 44...operation panel, 44A...impact force switching button, 44B...display device, 45...first connection section, 46...second connection section, 47...lock ring, 51...stator, 52...rotor, 54...stator core, 56...front insulating member, 58...rear insulating member, 60...coil, 62...sensor board, 64...terminal portion, 66...motor shaft, 68...rotor core, 70... permanent magnet, 72... sleeve, 74... motor front bearing, 75... bearing retainer, 76... pinion gear, 77... motor rear bearing, 78... fan sleeve, 80... internal gear, 82... planetary gear, 84... pin, 90... disk portion, 94... spindle bearing, 96... housing rib, 98... retainer rib, 100... inner hole, 101... recess, 102... spring ball, 104... hammer washer, 106... hammer ball, 112... chuck, 114... flange portion, 116... anvil bearing, 118... front end portion, 120... anvil hole, 122... chuck sleeve, 124... chuck spring, 126... chuck washer, 127... chuck spring fixing member, 128... chuck ball, 130... chuck front hole portion, 132... chuck ball fixing portion, 140: mode change switch, 142: mode operation member, 142A: upper end (one end), 142B: lower end (the other end), 142F: mode operation member, 142R: mode operation member, 144: mode signal output device, 146: opening, 148: support member, 150: mode operation member (slide member), 150G: guide groove, 151: mode operation member (dial member), 152 ...mode operation member (lever member), 160...headlamp, 1421...main body member, 1422...cover member, 1423...elastic member, AX...rotation axis, BX...rotation axis, CX...rotation axis, Ca...inflection point, Cb...inflection point, Cc...inflection point, Cd...inflection point, H8...dimension, H142...dimension, L4...dimension, L6...dimension, L29...dimension, W4...dimension, W8...dimension, W6...dimension, W29...dimension.

Claims (5)

A main body including a motor that rotates around a rotation shaft extending in the front-rear direction;
A handle portion is disposed rearward of the main body portion and extends in a vertical direction;
a battery mounting section having a mounting surface on which a battery is mounted and an operation surface including an operation panel, the battery mounting section being connected to a lower end of the handle section;
a first connection portion that connects a rear portion of the main body portion and an upper end portion of the handle portion;
a second connection portion that connects a lower portion of the main body portion and the battery mounting portion;
a trigger operating member disposed at a front portion of the handle portion and configured to activate a motor;
a display device disposed on an upper surface of the battery mounting portion, the display device being disposed on a front side of the handle portion and a rear side of the second connection portion;
a forward/reverse changeover switch disposed on an upper portion of the handle portion for changing a rotation direction of the motor;
a push button type mode operation member disposed on an upper portion of the handle portion and adapted to change the rotation speed of the motor;
Equipped with
Electric screwdriver . The mode operation member is disposed on an upper surface of the handle portion.
2. The power screwdriver of claim 1. The mode operation member is disposed on a rear surface of the handle portion.
2. The power screwdriver of claim 1. The mode operation member is provided at the front of the handle portion.
2. The power screwdriver of claim 1. The mode operation member is disposed below the trigger operation member.
5. The power screwdriver of claim 4 .

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