JP7182998B2 - Electric tool - Google Patents

Description

The present invention relates to an electric power tool such as an electric vibration driver drill or an electric driver drill.

As disclosed in Japanese Unexamined Patent Application Publication No. 2012-218088 (Patent Document 1), in a vibration driver drill provided with a mode switching ring 79 for switching between clutch mode, drill mode, and vibration mode, the clutch mode is switched to the drill mode or the vibration mode. Then, the regulating pin 107, which has entered the notch 110 of the inserting portion 81 of the mode switching ring 79 from behind, comes out of the notch 110, rides on the rear edge of the inserting portion 81 and retreats, and the planetary gear reduction mechanism It is known to engage with the external teeth 32 of the internal gear 23C at 20 to lock the rotation of the internal gear 23C.
The regulating pin 107 has a large-diameter head 108 at its front end, and is biased forward by a coil spring 109 mounted on the rear side of the head 108 .

JP 2012-218088 A

A primary object of the present invention is to provide a power tool that is radially compact.

In order to achieve the above object, the invention according to claim 1 includes a motor, a planetary gear driven by the motor, an internal gear that meshes with the planetary gear, and an internal gear that enters radially outwardly of the internal gear. and a plurality of elastic bodies for urging each of the internal gear lock pins, wherein the plurality of elastic bodies is characterized in that the center axis is different from the center axis of each of the internal gear lock pins and are arranged in the circumferential direction.
According to a second aspect of the invention , in the above invention, a plurality of the elastic bodies are arranged radially inward of each of the internal gear lock pins.
According to a third aspect of the present invention, each of the internal gear lock pins is held by a pin holder, and the plurality of elastic bodies bias the internal gear lock pins via the pin holders. It is characterized by
According to a fourth aspect of the invention, there is provided a clutch pin in contact with the internal gear and a clutch washer in contact with the clutch pin. An elastic body holding portion for holding the elastic body in the pin holder is arranged.
According to a fifth aspect of the present invention , there is provided a clutch pin in contact with the internal gear and a clutch washer in contact with the clutch pin, and the clutch washer is provided for each of the internal gear locks. It is characterized by having a trough through which the pin passes.
According to a sixth aspect of the present invention, in the above invention, the internal gear has a plurality of protrusions that protrude radially outward and are arranged in the circumferential direction, and each of the internal gear lock pins is arranged in the circumferential direction. It is characterized by entering between the protrusions in .
According to a seventh aspect of the present invention, there is provided a motor, a planetary gear driven by the motor, an internal gear meshing with the planetary gear, an internal gear lock pin for preventing rotation of the internal gear, and the internal gear. It has a plurality of elastic bodies for biasing the gear lock pin, a pin holder that holds the internal gear lock pin, a clutch pin that contacts the internal gear, and a clutch washer that contacts the clutch pin. The plurality of elastic bodies have central axes different from the central axis of the internal gear lock pin, are arranged in a circumferential direction, and bias the internal gear lock pin via the pin holder. and an elastic body holding portion for holding the elastic body in the pin holder is disposed radially inward of the clutch washer.
According to an eighth aspect of the invention, there is provided a motor, a planetary gear driven by the motor, an internal gear meshing with the planetary gear, an internal gear lock pin for preventing rotation of the internal gear, and the internal gear. It has a plurality of elastic bodies for urging a gear lock pin, a clutch pin that contacts the internal gear, and a clutch washer that contacts the clutch pin. is different from the central axis of the internal gear lock pin, and are arranged in the circumferential direction, and the clutch washer has a valley through which the internal gear lock pin passes. .

The present invention provides a power tool that is radially compact.

1 is a perspective view of a driver drill according to the present invention; FIG. FIG. 2 is a right side view of FIG. 1; 2 is a front view of FIG. 1; FIG. 2 is a top view of FIG. 1; FIG. 3 is a cross-sectional view along KAZAMADO--KAZAMADO in FIG. 2; FIG. FIG. 3 is a cross-sectional view along BB-BB in FIG. 2; 3 is a cross-sectional view along GRIP1-GRIP1 in FIG. 2; FIG. 3 is a GRIP2-GRIP2 cross-sectional view of FIG. 2; FIG. 3 is a cross-sectional view along GRIP3-GRIP3 in FIG. 2; FIG. FIG. 2 is a right side view of the gear assembly in the electric vibration driver drill of FIG. 1; Figure 11 is a front view of Figure 10; Figure 11 is a rear view of Figure 10; FIG. 11 is a perspective view in which only the front part of FIG. 10 is exploded; Figure 11 is an exploded perspective view of a portion of Figure 10; 11 is an exploded perspective view of another portion of FIG. 10; FIG. FIG. 12 is a FRONT-FRONT sectional view of FIG. 11; FIG. 12 is a TOP-TOP cross-sectional view of FIG. 11; 12 is a cross-sectional view along NEJI1-NEJI1 in FIG. 11; FIG. FIG. 17 is a cross-sectional view taken along line QQ of FIG. 16; FIG. 17 is a cross-sectional view taken along line AA of FIG. 16; FIG. 21 is a CAM-CAM sectional view of FIG. 20; FIG. 17 is a cross-sectional view taken along the line BB of FIG. 16; 17 is a cross-sectional view taken along the line CC of FIG. 16; FIG. FIG. 17 is a cross-sectional view taken along line TT of FIG. 16; FIG. 25 is a cross-sectional view taken along line GG of FIG. 24; FIG. 17 is a cross-sectional view taken along line DD of FIG. 16; FIG. 27 is a cross-sectional view taken along line VV of FIG. 26; (a) is a ZZ sectional view of FIG. 16, and (b) is an AA-AA sectional view of (a). FIG. 17 is a cross-sectional view (at the time of rotation) taken along line SS of FIG. 16; FIG. 17 is a sectional view taken along the line SS of FIG. 16 (when stopped); FIG. 17 is a cross-sectional view taken along line EE of FIG. 16; FIG. 17 is a cross-sectional view taken along line FF of FIG. 16; FIG. 17 is a cross-sectional view along JJ of FIG. 16; FIG. 17 is a cross-sectional view taken along line HH of FIG. 16; FIG. 17 is a cross-sectional view taken along line LL of FIG. 16; FIG. 11 is a diagram of FIG. 10 with a part of the outer shell removed; FIG. 17 is a diagram similar to FIG. 16 in vibration mode and high-speed mode; FIG. 38 is a cross-sectional view along WW in FIG. 37; FIG. 37 is a view in a mode other than the clutch mode when part of the internal mechanism is removed in FIG. 36; FIG. 11 is a view similar to FIG. 10 in a clutch mode; FIG. 18 is a view similar to FIG. 17 in clutch mode and high speed mode; FIG. 39 is a view similar to FIG. 39 in the clutch mode;

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention and modifications thereof will be described below with reference to the drawings as appropriate.
The front, rear, top, bottom, left, and right in the form and modification are defined for convenience of explanation, and may change depending on at least one of the working conditions and the state of the moving member.
In addition, the present invention is not limited to the following forms and modifications.

FIG. 1 is a perspective view of an electric vibration driver drill 1, which is an example of an electric power tool. FIG. 2 is a right side view of the electric vibration driver drill 1. FIG. FIG. 3 is a front view of the electric vibration driver drill 1. FIG. FIG. 4 is a top view of the electric vibration driver drill 1. FIG. 5 is a KAZAMADO--KAZAMADO cross-sectional view of FIG. FIG. 6 is a cross-sectional view along BB-BB in FIG. FIG. 7 is a cross-sectional view along GRIP1-GRIP1 in FIG. FIG. 8 is a GRIP2-GRIP2 cross-sectional view of FIG. FIG. 9 is a cross-sectional view along GRIP3-GRIP3 in FIG.
An electric vibration driver drill 1 has a housing 2 forming its outer shell.
The electric vibration driver drill 1 has a tubular main body 4 whose center axis is oriented in the front-rear direction, and a grip part 6 formed so as to protrude downward from the lower part of the main body 4 . 2, the right is the front and the top is the top, and in FIG. 4, the top is the left and the right is the front.
The grip portion 6 is a portion that is gripped by the user, and a trigger-type switch lever 8 that can be pulled by the user's fingertips is provided at the upper end portion of the grip portion 6 . The switch lever 8 protrudes from the switch main body 9 (see FIGS. 7 and 8).

As shown in FIGS. 5 and 6, a motor 10 is accommodated in the rear portion of the body portion 4 of the electric vibration driver drill 1. As shown in FIGS. A gear assembly 12 is arranged on the front side of the motor 10 . A chuck 14 capable of gripping a bit (tipped tool) is provided on the front side of the gear assembly 12 .
A motor 10 is a drive source for the electric vibration driver drill 1 . The rotation of the motor 10 is reduced by the gear assembly 12 and transmitted to the chuck 14 and the bit. A part of the motor 10 is omitted in FIG.

The housing 2 includes a resin body housing 20 that holds the motor 10 and the switch body 9 and the like, and a resin rear cover 22 that covers the rear of the motor 10 .

The body housing 20 contains the outer shell of the grip portion 6 .
The body housing 20 has a half-split left body housing 20a and a right body housing 20b. The left body housing 20a has a plurality of screw bosses, and the right body housing 20b has screw holes corresponding to the screw bosses. The left body housing 20a and the right body housing 20b are held together by lateral screws 24 that enter each set of screw holes and screw bosses.
The rear portions of the main body portion 4 of the left main housing 20a and the right main housing 20b are joined to form an opening, and a rear cover 22 is fixed to the opening by a plurality of screws 25 extending in the front-rear direction. there is Each screw 25 is arranged vertically (only the upper screw 25 is shown), and the rear cover 22 is securely fixed.
A plurality of intake ports 20c extending in the vertical direction are opened so as to line up in the front-rear direction in the upper and lower sides of the rear end portions of the left main housing 20a and the right main housing 20b. That is, the plurality of air intake ports 20c are formed in a continuous slit shape arranged along the front adjacent portion of the rear cover 22. As shown in FIG. A plurality of exhaust ports 22a extending in the front-rear direction are formed in a vertical line on the side of the rear cover 22 behind the respective intake ports 20c.

As shown in FIGS. 2 and 3, behind the switch lever 8, a normal/reverse switching lever 26, which is a switch for switching the rotation direction of the motor 10, penetrates left and right in the boundary region between the body portion 4 and the grip portion 6. It is designed to
Further, above the switch lever 8 and in front of the forward/reverse switching lever 26, a plurality of (two) lights 28 capable of illuminating the front are provided so as to be arranged side by side. Each light 28 is an LED here.

A lower end portion of the grip portion 6 serves as a battery mounting portion 30 extending outward from the upper portion thereof, and a battery 32 is detachably held below the battery mounting portion 30 by a battery button 32a. The battery 32 is a lithium ion battery and contains a plurality of cells (not shown). The cells are in the shape of an axially long cylinder and are oriented in the left-right direction.
A display unit 33 is provided on the front upper portion of the battery mounting portion 30 (the front upper surface portion of the widened lower portion of the grip portion 6) to display the state of the electronic gear by lighting modes of a plurality of lamps.
The battery 32 is attached by sliding it from the front to the rear of the battery attachment portion 30 with the battery terminal portion facing up and the raised portion 32b facing up and forward. When mounted, the rear portion of the raised portion 32b hits the front portion of the battery mounting portion 30, and the battery terminal portion contacts the battery mounting terminal portion of the battery mounting portion 30. As shown in FIG. Also, when mounted, the battery claws that are urged upward by the elastic member and protrude from the upper surface of other portions of the battery 32 enter the battery mounting recesses that are recessed upward provided in the lower front portion of the battery mounting portion 30 . On the other hand, when the battery 32 is removed, the battery button 32a connected to the elastic member of the battery claw is operated, and the battery 32 is slid forward while the battery claw is removed from the battery mounting recess.
A hook 34 and a bit holder 35 are arranged on the battery mounting portion 30, respectively. The hook 34 and bit holder 35 can be attached to the left or right portion of the battery attachment portion 30 with screws 36 . The hook 34 includes a U hook portion 34a having a "U" shape when viewed from the front, a first loop hook portion 34b having an "Ω" shape when viewed from the side, a portion along the first loop hook portion 34b, and a loop-shaped portion when viewed from the top. and a second loop hook portion 34c having The parallel front end portion of the first loop hook portion 34b and both ends of the second loop hook portion 34c are held in a tubular portion 34d formed at the upper end portion of the U hook portion 34a and having the longitudinal direction in the axial direction. ing. The bit holder 35 detachably holds a plurality of (two) bits 35a by sliding forward. The bit 35a can be attached to the bit holder 35 by sliding it backward.
As shown in FIGS. 2 and 9, the battery mounting portion 30 holds a control circuit board 38 of a controller for controlling the motor. The control circuit board 38 has a columnar capacitor 38a protruding upward from other parts, and a microcomputer. The control circuit board 38 is electrically connected to the motor 10 by power supply leads and signal leads (not shown). The control circuit board 38 is also electrically connected to the battery mounting terminal portion of the battery mounting portion 30 .

As shown in FIGS. 5 and 6 , the motor 10 is a brushless motor and includes a cylindrical stator 40 and a rotor 41 arranged inside the stator 40 .
The rotor 41 includes a cylindrical motor shaft extending in the front-rear direction, a pinion 43 (FIG. 6) integral with the front end of the motor shaft, a cylindrical rotor core arranged around the central portion of the motor shaft, and permanent magnets disposed within the rotor core.
A cooling fan 44 is attached to the rear of the motor shaft via a metal insert bush (not shown). Fan 44 is a centrifugal fan. Since the insert bushing is press-fitted, the fixing force of the fan 44 to the motor shaft is high.
Each exhaust port 22 a is positioned radially outward of the fan 44 .
A rear motor bearing that rotatably supports the rear end of the motor shaft is held on the rear inner surface of the rear cover 22 on the rear side of the fan 44 .
The stator 40 includes a cylindrical portion whose axial direction is the front-rear direction, a stator core 45 having a plurality of teeth 45a protruding radially inward from the inner surface of the cylindrical portion, and a ring-shaped stator core 45 attached to the front and rear of the stator core 45, respectively. a front insulating member 46A and a rear insulating member 46B; a coil 47 wound around each tooth 45a via the front insulating member 46A and the rear insulating member 46B; a sensor substrate 48 attached to the front side of the front insulating member 46A; and an annular synthetic resin sheet metal member 49 including a plurality of arcuate sheet metal members 49 attached thereto.
The sensor board 48 detects the rotational position of the rotor 41 (permanent magnet) and transmits it to the control circuit board 38 .
The sheet metal of the sheet metal member 49 electrically connects the coils 47 to each other in a predetermined manner and is connected to the power lead to the control circuit board 38 .

As shown in FIGS. 10 to 42, the gear assembly 12 includes, as its outer shell, a cylindrical gear case 50 and a plate-like (dish-like) motor bracket 51 arranged behind the rear end of the gear case 50. , a metal gear housing 52 arranged in front of the gear case 50 and having a double inner and outer cylindrical shape, and a gear housing 52 arranged in front of the gear housing 52, exposed at the upper front part of the housing 2, and externally mounted on the housing 2. It has a clutch ring 53 as a clutch switching ring and a mode switching ring 54 mounted on the housing 2 like the clutch ring 53 on the front side thereof.
A spindle 55 is arranged along the central axis of the gear assembly 12 radially inward of the front portion of the outer shell of the gear assembly 12 . The tip of the spindle 55 protrudes forward from the outer shell of the gear assembly 12 .
The spindle 55 is a columnar member whose axial direction is the front-rear direction. A spindle flange 55a extending radially outward at the central portion in the front-rear direction and a rear portion of the spindle flange 55a each having a smaller diameter than the front portion thereof. A front step portion 55b, a middle step portion 55c, and a rear step portion 55d, a clip groove 55e formed in the front side of the middle step portion 55c in the circumferential direction, and a spindle extending back and forth at the center of the front portion and open at the front end. It has a hole 55f. The spindle hole 55f is a bolt hole having a thread groove. A male threaded portion (not shown) is formed on the outer surface of the front end portion of the spindle 55 on the radially outward side of the spindle hole 55f.
The chuck 14 has a female threaded portion corresponding to the male threaded portion of the spindle 55 (not shown). The chuck 14 is fixed to the spindle 55 by receiving the male threaded portion of the spindle 55 in the female threaded portion and inserting a bolt (not shown) into the spindle hole 55f. At least one of the spindle 55 and chuck 14 can be regarded as an output shaft.

The gear case 50 has a cylindrical gear case base portion 50a, and screws having screw holes in the centers of projecting pieces projecting radially outward are provided on the upper right, lower right, upper left, and lower left of the gear case base 50a. A hole 50b is formed. Similarly, screw hole portions 51b and 52b are formed in the rear portion of the motor bracket base portion 51a of the motor bracket 51 and the outer cylindrical portion 52a of the gear housing 52, which are cylindrical with a bottom. The screw hole portion 51b protrudes radially outward and forward. The screw hole portion 52b protrudes radially outward. A common screw 56 is passed through the upper right screw holes 50b, 51b and 52b, and the same applies to the lower right, upper left, and lower left. Since the gear case 50 and the gear housing 52 (and the motor bracket 51) are fastened together by the common connecting means, the adhesion between them is improved, the internal mechanism is protected, and the internal mechanism is free from grease or the like. When applied, leakage of grease or the like can be prevented. In addition, the gear assembly 12 can be made more compact than when the connecting member between the motor bracket 51 and the gear case 50 and the connecting member between the gear case 50 and the gear housing 52 are provided separately.
On the front outer surface of the outer cylindrical portion 52a of the gear housing 52 and circumferentially adjacent to the screw hole portion 52b (under the upper screw hole portion 52b and above the lower screw hole portion 52b), A side handle mounting portion 52c, which is a recess extending in the front-rear direction, is formed to receive a "C"-shaped handle-side mounting portion of a side handle (not shown). A side handle extending in the left-right direction is attached by inserting the bifurcated tip of the handle side attachment portion into the pair of side handle attachment portions 52c on the right or left side. Even if the side handle tries to rotate around the handle-side mounting portion, the screw hole portion 52b projecting outward in the circumferential direction stops the handle-side mounting portion, so that the rotation is prevented and the mounting state of the side handle is stabilized. maintained.

The gear assembly 12 is secured by screw holes 57 arranged radially outward of the screw holes 52b of the gear housing 52 and screws 58 that enter screw holes formed in openings of the main body 4 of the main body housing 20. , is mounted in front of the opening of the body housing 20 . In the screw hole portions 57, the horizontal interval between the upper two pieces is narrower than the horizontal interval between the lower two pieces. Therefore, the arrangement of the screw holes 57 conforms to the shape of the columnar main body 4 from which the grip 6 extends downward, which contributes to making the upper part compact in the left-right direction.
As shown in FIG. 6, the inner surface of the opening of the body housing 20 is provided with a rib 20d protruding radially inward. The rib 20 d is a side surface of the gear case base portion 50 a and is adjacent to the rear side of the enlarged diameter portion with respect to the gear housing 52 . The rib 20d receives a reaction force of stress deformation generated in the gear case 50 due to the operation of the internal mechanism of the gear assembly 12 (such as a middle planetary gear mechanism 70, which will be described later). Therefore, the gear assembly 12 is reliably held.
Projections 59 are provided on the left and right sides of the rear portion of the lower surface of the outer cylindrical portion 52a of the gear housing 52 so as to protrude downward and outward in the left-right direction. Each projecting body 59 is engaged with the inner surface of the body housing 20 to prevent the gear assembly 12 and the body housing 20 from being separated.
The front, side, and upper portions of the gear housing 52 are exposed and form part of the outer shell of the main body 4 , and the gear housing 52 forms part of the housing 2 .

A central hole 51c of the motor bracket 51 receives a front motor bearing (not shown) for rotatably supporting a pinion 43 (see FIG. 6) at the front end of the motor shaft. As particularly shown in FIG. 35, the motor bracket 51 has a plurality of (seven) projections 51d protruding radially outward from the outer surface of the cylindrical portion of the motor bracket base 51a. Rotation is stopped by entering the formed inner groove 50c extending in the front-rear direction and recessed radially outward.
At least one of the motor bracket 51, the clutch ring 53, the mode switching ring 54, and the spindle 55 may be regarded as not a component of the gear assembly 12, and the motor bracket 51 is a component of the motor 10. It may be caught. Also, the chuck 14 , the front motor bearing and/or the pinion 43 may be regarded as components of the gear assembly 12 .

Further, the gear assembly 12 has a three-stage planetary gear mechanism inside, which decelerates the rotation of the motor shaft and transmits it to the spindle 55 . That is, the gear assembly 12 includes a rear planetary gear mechanism 60 (first stage reduction mechanism), a middle planetary gear mechanism 70 (second stage reduction mechanism), and a front planetary gear mechanism 80 (third stage reduction mechanism). have

The rear planetary gear mechanism 60, as also shown in FIGS. and a carrier 66 that rotatably supports each planetary gear 64 via a needle bearing 65 .
The internal gear 62 has a plurality of (four) projections 62b projecting radially outward from a ring-shaped internal tooth portion 62a, and a plurality of slits 51e extending in the front-rear direction formed in the cylindrical surface of the motor bracket base portion 51a. , and an inner groove 50d formed on the inner surface of the rear end portion of the gear case base portion 50a and extending in the front-rear direction and recessed radially outward to prevent rotation.
Each planetary gear 64 meshes with the pinion 43 (see FIG. 6) of the motor shaft.
The carrier 66 has five pins 66b projecting rearwardly at equal circumferential intervals from the rear surface of a disk-shaped portion 66a having a central hole, one planet gear 64 for each pin 66b. and needle bearings 65 are supported. Further, the carrier 66 has an external gear 66c cylindrically protruding forward from the center of the front surface of the disk-shaped portion 66a. Furthermore, meshing teeth 66d are provided on the front outer surface of the disk-shaped portion 66a.
Since the planetary gear 64 is supported by the needle bearings 65, the support strength is increased compared to ball bearings. Therefore, even if the planetary gear 64 is made thin in the axial direction (front-to-rear direction), it is possible to ensure the same level of strength as a ball bearing, and the planetary gear 64 or the rear planetary gear mechanism 60, and by extension, the electric vibration driver drill 1 can be moved forward and backward. more compact in direction.
A washer 68 is arranged between each planetary gear 64 and the motor bracket 51 .

32 and 33, the middle planetary gear mechanism 70 includes an internal gear 72, a plurality of (five) planetary gears 74 having external teeth that mesh with the internal teeth of the internal gear 72, and It has a carrier 76 that rotatably supports planetary gears 74 .
A plurality of external teeth 72b projecting in the radial direction and extending in the front-rear direction are provided at predetermined intervals in the circumferential direction on the front portion of the outer surface of the ring-shaped internal tooth portion 72a of the internal gear 72. A coupling groove 72c extending in the circumferential direction is provided at the rear portion of the outer surface. In addition, meshing teeth 72d that can mesh with the meshing teeth 66d of the first-stage carrier 66 are provided at the opening side of the rear surface of the internal gear 72. As shown in FIG.
Each planetary gear 74 meshes with the external gear 66c of the carrier 66 of the first stage.
The carrier 76 has five pins 76b projecting rearwardly from the rear surface of a disc-shaped portion 76a having a hole in the center, and one planetary gear 74 is supported on each pin 76b. Further, the carrier 76 has an external gear 76c projecting forward in a cylindrical shape from the center of the front surface of the disk-shaped portion 76a.

As also shown in FIG. 32 , a coupling ring 77 that is held in the rear portion within the gear housing 52 is arranged outside and forward of the internal gear 72 . The inner peripheral surface of the annular coupling ring base portion 77 a of the coupling ring 77 is provided with the same number of internal teeth 77 b as the external teeth 72 b of the internal gear 72 that protrude radially inward and extend in the front-rear direction. A plurality (six) of protrusions 77c projecting outward and extending in the front-rear direction are provided on the outer peripheral surface of the coupling ring base portion 77a at predetermined intervals in the circumferential direction. Each external tooth 72 b of the internal gear 72 can fit between any internal tooth 77 b of the coupling ring 77 .
The coupling ring 77 is arranged between the arcuate ribs 50e formed in the front end portion of the gear case base portion 50a at regular intervals in the circumferential direction, and behind the outer cylindrical portion 52a of the gear housing 52. Rotation is stopped by entering an inner groove 52d extending in the front-rear direction and recessed radially outward, which is formed on the inner surface of the end portion. A projecting portion 50f projecting radially outward is formed on the radially outward surface of the lower arcuate rib 50e. The protruding portion 50f is inserted into an inner groove 52e formed in the inner surface of the rear end portion of the outer cylindrical portion 52a of the gear housing 52 and extending in the front-rear direction and recessed radially outward.

On the other hand, as also shown in FIG. 33, a speed switching ring 78 is arranged outside the rear portion of the internal gear 72 . At the upper portion of the ring-shaped speed switching ring base portion 78a of the speed switching ring 78, a connecting piece 78b protrudes rearward and upward in an "L" shape when viewed from the side. , projecting pieces 78c protrude radially outward and rearward.
As also shown in FIG. 34, the gear case 50 is provided with a slit 50g extending forward from the upper rear portion, and the slit 50g receives the lower end portion of the upward projecting portion of the connecting piece 78b. The upper portion of the upwardly protruding portion of the connecting piece 78b is attached to the lower portion of a speed switching lever 79 (see FIGS. 1, 2, and 4) provided in the upper portion of the housing 2 so as to be slidable forward and backward. , not shown). The front portion of the speed switching lever 79 is inserted into a hole portion 52f formed in the upper portion of the outer cylindrical portion 52a of the gear housing 52 so as to extend forward from the rear end thereof. Upper screw hole portions 57 are arranged on both left and right sides of the hole portion 52f.
As shown in FIG. 33, the inner surface of the gear case base 50a is provided with longitudinal guide grooves 50h corresponding to the projecting pieces 78c of the speed switching ring 78. Each guide groove 50h has a corresponding A projecting piece 78c is inserted to support the speed switching ring 78 so as to move only in the forward and backward directions.
In addition, a total of two pins 78d extending radially inward from the left and right projecting pieces 78c are provided. The outer head of each pin 78d contacts the outer surface of each of the left and right projecting pieces 78c, and the inner tip of each pin 78d that is thinner than the head of each pin 78d protrudes radially inward from the inner surface of each projecting piece 78c to form an internal gear. 72 in the coupling groove 72c.

When the speed switching lever 79 is brought forward, the speed switching ring 78 moves forward through the connecting piece 78b, and the internal gear 72 keeps meshing with the planetary gears 74 through the pins 78d or coupling grooves 72c. Move forward. Then, the outer teeth 72b are inserted between the inner teeth 77b of the coupling ring 77 to restrict the rotation of the internal gear 72 in the circumferential direction, and the planetary gears 74 rotate around the fixed internal gear 72. The rotation, which is reduced in speed from the rotation of the first-stage external gear 66c, is transmitted to the external gear 76c of the carrier 76. As shown in FIG. That is, when the speed switching lever 79 is moved forward, a low speed mode is entered in which deceleration by the middle planetary gear mechanism 70 of the second stage functions.
On the other hand, as shown in FIGS. 37 and 41, when the speed switching lever 79 (see FIGS. 1, 2, and 4) is left behind, the speed switching ring 78 similarly moves rearward, and the internal gear 72 rotates. It moves backward while maintaining meshing with each planetary gear 74 . Then, the external teeth 72b come out from between the internal teeth 77b of the coupling ring 77, releasing the restriction on the rotation of the internal gear 72 in the circumferential direction, and the internal gear 72 moves against the meshing teeth 66d of the carrier 66 of the first stage. The meshing teeth 72d are meshed, the internal gear 72 which is not fixed in the circumferential direction and the first stage carrier 66 rotate together, and the rotation equivalent to the rotation of the external gear 66c is transmitted to the external gear 76c. That is, when the speed switching lever 79 is left behind, the speed mode is changed to the high speed mode in which the deceleration by the middle planetary gear mechanism 70 of the second stage is cancelled.
A rib 78e extending in the front-rear direction and protruding downward is provided at the center in the left-right direction of the lower surface of the connecting piece 78b. Therefore, the rigidity of the connecting piece 78b is ensured to prevent deflection, and the position of the internal gear 72 after being moved by the speed switching ring 78 is stabilized. The rib 78e is inserted into a groove 51f provided on the upper surface of the motor bracket base 51a so as to extend in the front-rear direction and be recessed downward. A slit 50g of the gear case 50 is positioned above the groove 51f.

As shown in FIGS. 30 and 31, the front planetary gear mechanism 80 has an internal gear 82 that is rotatable in the gear housing 52 in the circumferential direction, and external teeth that mesh with the internal teeth of the internal gear 82. and a carrier 86 that rotatably supports each planetary gear 84 .
A plurality of (six) cam projections 82b projecting forward are provided on the front surface of the cylindrical internal tooth portion 82a of the internal gear 82 at predetermined intervals in the circumferential direction. A plurality of (six) protruding portions 82c protruding radially outward are provided on the outer surface of the internal tooth portion 82a. Each projecting portion 82c is arranged in the central portion between the cam projections 82b in the inner tooth portion 82a.
Each planetary gear 84 meshes with the external gear 76c of the carrier 76 of the second stage.
The carrier 86 has a plurality of (six) pins 86b projecting rearward from the rear surface of a disc-shaped portion 86a having a hole in the center, and one planetary gear 84 is supported by each pin 86b. In addition, the carrier 86 has a plurality of (four) projecting bodies 86c projecting forward from the center of the front surface of the disc-shaped portion 86a in a quarter-cylindrical shape and arranged in the circumferential direction (see FIGS. 14, 28(a), etc.). ).

As also shown in FIGS. 19 and 20, the clutch ring 53 is arranged radially outward of the inner cylindrical portion 52g of the gear housing 52. As shown in FIG. The inner cylindrical portion 52g has a cylindrical shape with a smaller diameter than the outer cylindrical portion 52a. The front end of the inner tubular portion 52g is located forward of the front end of the outer tubular portion 52a .
The clutch ring 53 has an annular groove 53b recessed forward from the rear end portion of a cylindrical clutch ring base portion 53a having an outer uneven surface. The clutch ring 53 is positioned in front of a ring-shaped rib 52h (see FIGS. 10, 13, etc.) which is formed to protrude radially outward at the front opening of the outer cylindrical portion 52a of the gear housing 52. With the groove 53b inserted, it is provided rotatably around the axis.
A plurality of positioning recesses 53c are formed on the radially outer inner surface of the groove 53b of the clutch ring 53 so as to be recessed radially outward at equal intervals in the circumferential direction. On the other hand, a pair of protrusions 52i projecting forward are provided on the upper right of the front opening of the outer cylindrical portion 52a of the gear housing 52, and the central portions of these protrusions 52i bulge radially outward. A leaf spring 88 that is biased radially outward is locked. The bulging portion of the leaf spring 88 can enter any one of the positioning recesses 53c, gives a click feeling to the rotation of the clutch ring 53, and positions the clutch ring 53 in the rotational direction.
A threaded portion 53d having a helical thread is provided on the inner surface of the clutch ring base portion 53a.

As also shown in FIGS. 19 and 20, a ring-shaped spring holder 90 is arranged radially inward of the clutch ring 53 .
A threaded portion 90b having a thread that meshes with the threaded portion 53d of the clutch ring 53 is formed on the outer surface of a cylindrical spring holder base portion 90a of the spring holder 90. When the clutch ring 53 rotates, the spring holder 90 moves forward and backward. is moved to
The rear portion of the spring holder base portion 90a protrudes radially outward in a semicircular shape at a plurality (12) locations with respect to the front portion, and the radially inner portions of the semicircular protruding portions are formed in a set of a predetermined number (four). A total of three flange portions 90c (see FIGS. 15, 24, etc.) connected by , and spring holding portions 90d (FIG. 15, FIG. 17, see FIG. 18, etc.). Between each flange portion 90c in the circumferential direction is a valley portion 90e recessed inward in the circumferential direction with respect to the outer shape of each flange portion 90c (see FIGS. 15, 24, etc.).
A rib 90f projecting rearward from the rear end portion of the spring holder base portion 90a is provided between predetermined spring holding portions 90d (see FIGS. 15, 17, etc.). The rearward protrusion height of each rib 90f is the same as the protrusion height of the spring holding portion 90d. Each rib 90f restricts radially outward movement of various members arranged radially inward, holds the members, and prevents them from falling off.
Further, the lower flange portion 90c has a projecting piece 90g projecting radially outward between the semicircular projecting portions at the lower portion.

As shown in FIG. 26, each spring holding portion 90d holds a clutch pin coil spring 92 as an elastic body. A single washer 94 (clutch washer) having the same shape as the flange portion 90c is provided on the rear side of each clutch pin coil spring 92. As shown in FIG. The front end of each clutch pin coil spring 92 contacts the rear surface of the flange portion 90 c of the spring holder 90 , and the rear end of each clutch pin coil spring 92 contacts the front surface of the washer 94 .
The washer 94 has a plurality of (twelve) projecting portions 94b projecting radially outward in a semicircular shape from a ring-shaped washer base portion 94a. Between adjacent radially outward semicircular projections of the washer 94, there is an extending portion 94c extending radially inward in an arc from the radially inner portion of the washer base portion 94a. , a total of 6 locations. Furthermore, a total of three troughs 94d formed in the same manner as the troughs 90e of the spring holder 90 are provided. A projecting piece 94e projecting radially outward is provided between the projecting portions 94b in the lower portion of the washer 94. As shown in FIG.

19 to 26, the spring holder 90, the clutch pin coil spring 92 and the washer 94 are contained in the gear housing 52 between the inner tubular portion 52g and the outer tubular portion 52a. The inner surface of the front portion of the outer cylindrical portion 52a has an outer shape similar to that of the flange portion 90c or the washer 94. As shown in FIG. The spring holder 90 is prevented from rotating by the flange portion 90c and the projecting piece 90g. The washer 94 is prevented from rotating by the projecting portion 94b and the projecting piece 94e. At least one of the projecting pieces 90g and 94e may be omitted.
As shown in FIG. 28(a), the front surface of a ring-shaped wall portion 52j that spreads vertically and horizontally in the gear housing 52 and connects the inner cylindrical portion 52g and the outer cylindrical portion 52a is provided with a flange portion 90c and a washer 94. has the same shape as A circular hole is formed in a portion of the wall portion 52j located behind each extended portion 94c of the washer 94, and a cylindrical clutch pin sleeve 95 is inserted into the hole to form a cylindrical clutch. of clutch pins 96 are inserted from the front.
28(a) and 28(b), each clutch pin sleeve 95 protrudes radially outward from a cylindrical clutch pin sleeve base portion 95a and from the outer surface of the front end portion of the clutch pin sleeve base portion 95a. and a pair of flanges 95b. Each flange 95b faces each other. By providing each flange 95b, the portion supported by the gear housing 52 is increased by that amount, and the lengths of the clutch pin sleeve 95 and the clutch pin 96 in the front-rear direction are shortened while the support strength is maintained.
Each clutch pin 96 has a columnar shape with a spherically rounded rear end portion, and is integrally held by the clutch pin sleeve 95 by inserting the front portion into the clutch pin sleeve base portion 95a.
The front end of each clutch pin sleeve 95 and the front end of each clutch pin 96 contact the rear surface of washer 94 .
A rear end portion of each clutch pin 96 can contact the front surface of the cylindrical internal tooth portion 82 a of the internal gear 82 of the front planetary gear mechanism 80 .

When the rotational position is changed by twisting the clutch ring 53, the longitudinal position of the spring holder 90 is changed, the distance between the flange portion 90c and the washer 94 is changed, and the elastic force of each clutch pin coil spring 92 is adjusted. The washer 94 pushes each clutch pin 96 via each clutch pin sleeve 95 according to the elastic force of the clutch pin coil spring 92 , and each clutch pin 96 pushes one of the cam projections of the third stage internal gear 82 . 82b, rotation or rotation regulation of the internal gear 82 according to the elastic force of the clutch pin coil spring 92 is performed.
That is, as shown in FIG. 30, each clutch pin 96 presses the front surface of the internal gear 82 according to the elastic force of each clutch pin coil spring 92, and when the torque is less than a predetermined torque corresponding to the elastic force, the cam projection The internal gear 82 is fixed by stopping 82b. The side surface of the cam projection 82b has a spherically constricted portion that matches the shape of the rear end portion of the clutch pin 96. As shown in FIG. The clutch pin 96 can sufficiently resist the rotational force of the third-stage internal gear 82 by contacting the constricted portion. Then, as shown in FIG. 29, when the torque exceeds that torque, the cam protrusions 82b move the respective clutch pins 96 forward against the elastic force, thereby relatively overcoming them. This overriding is smoothly performed by the constricted portion. By this relative overriding, each clutch pin 96 permits the rotation of the internal gear 82 so that it can rotate. The rotation of the null gear 82 idly rotates the carrier 86 (each projecting body 86c) to operate the clutch.
A spring holder 90 , each clutch pin coil spring 92 , a washer 94 , each clutch pin sleeve 95 and each clutch pin 96 are components of a clutch mechanism 99 . Incidentally, the clutch mechanism 99 may include the cam projection 82b. Also, at least one of each clutch pin sleeve 95 and washer 94 may be omitted.
In the electric vibration driver drill 1, each clutch pin coil spring 92 is divided into a plurality (12 pieces) instead of one large one, so the spring constant is further increased compared to the case of one large coil spring. In addition, the contact length can be made smaller, and the length in the front-rear direction becomes shorter. In addition, various members can be arranged between the clutch pin coil springs 92 without interfering with their operation, and the electric vibration driver drill 1 can be made compact accordingly.

As also shown in FIGS. 24 and 25, a support ring 100 and a pin holder 102 behind the spring holder 90 are arranged radially inside the spring holder 90 .
The support ring 100 has a plurality of (three) trapezoidal cam projections 100b formed so as to protrude forward from other portions at the front end of a cylindrical support ring base 100a whose axial direction is the front-rear direction. , are equidistant in the circumferential direction (see FIGS. 15, 20, etc.). A plurality of (three) projecting pieces 100c projecting rearward from the rear end portion of the support ring base portion 100a are arranged between the cam projections 100b in the circumferential direction (see FIG. 15, etc.).
The pin holder 102 has a cylindrical pin holder base 102a whose axial direction is the front-rear direction. A plurality of (six) spring holding portions 102c (elastic body holding portions, see FIG. 15, etc.) protruding radially inward and rearward from the inner surface of 102a and arranged at equal intervals in the circumferential direction, and pin holder base portions 102a. and a plurality of (three) pin holding portions 102d protruding radially outward from the outer surface of the pin holding portion 102d and arranged at equal intervals in the circumferential direction. The recessed portion 102b and the pin holding portion 102d are displaced from each other in the circumferential direction.
A front end portion of a pin holder coil spring 104 as an elastic body is inserted in a rearward projecting portion of each spring holding portion 102c. The central axis of each pin holder coil spring 104 coincides with the central axis of the rearward projecting portion of the corresponding spring holding portion 102c. The rear portion of the pin holder coil spring 104 is contained in a hollow portion 52k (see FIGS. 25, 28(a), etc.) formed so as to be hollowed rearward from the front surface of the wall portion 52j of the gear housing 52 in a cylindrical shape. Each recessed portion 52k is formed at a total of six locations in the same arrangement as the spring holding portion 102c. The pin holder coil spring 104 biases the pin holder 102 forward.
As shown in FIGS. 24 and 25, each pin holding portion 102d holds a front end portion of a cylindrical internal gear lock pin 106 extending in the front-rear direction. A ring-shaped groove is formed in the front end portion of the internal gear lock pin 106, and the tip portion of the bifurcated pin holding portion 102d is inserted into the groove. Each pin holding portion 102d and each internal gear lock pin 106 pass between predetermined clutch pin coil springs 92 and outside valleys 90e and 94d of spring holders 90 and washers 94 (see FIGS. 24, 26, etc.). ). Further, each internal gear lock pin 106 passes through a correspondingly drilled pin hole 52l in the wall portion 52j of the gear housing 52 (see FIG. 25). A rear end portion of each internal gear lock pin 106 can advance and retreat with respect to the radially outer side of the third-stage internal gear 82 . As shown in FIG. 26 and the like, each pin holder coil spring 104 is arranged radially inward of each internal gear lock pin 106, and the central axis of each internal gear lock pin 106 is aligned with each pin holder coil spring. It is different from the central axis of 104. Each pin holder coil spring 104 is arranged radially inward of the washer 94 that contacts each clutch pin 96 .
The pin holder coil spring 104 biases each internal gear lock pin 106 forward via the pin holder 102 . A rear portion of each spring holding portion 102 c of the pin holder 102 is arranged radially inward of the washer 94 .

As shown in FIG. 21, the mode switching ring 54 has a tapered cylindrical shape that narrows forward and a mode switching ring base portion 54a that is uneven on the outside, and a cylindrical shape that protrudes rearward from the rear end portion of the inner surface of the mode switching ring base portion 54a. and a cam portion 54b.
The cam portion 54b has a total of three trapezoidal cam recesses 54c arranged in the same manner as the cam projections 100b of the support ring 100 (see FIGS. 15, 19, 36 and 39). A support ring 100 is arranged behind the cam portion 54b.
Further, as shown in FIGS. 11, 13, 15, and 40, on the inner surface of the mode switching ring 54 and in front of the cam portion 54b, there is provided a ring-shaped rotation restricting member protruding radially inward. A rib 54d is provided. A rotation permitting recess 54e that is recessed radially outward is formed in the upper portion of the rotation restricting rib 54d. A pair of plate spring locking portions 54f for locking the plate spring 114 as an elastic body is formed below the rotation restricting rib 54d.

The mode switching ring 54 is attached rotatably about an axis with the cam portion 54b arranged radially outward of the inner tubular portion 52g of the gear housing 52. As shown in FIG. A ring-shaped retainer 110 is fixed by a plurality of (four) screws 112 to the front end of the inner cylindrical portion 52g. Mode switching ring 54 is sandwiched between retainer 110 and clutch ring 53 .
11 and 40, the retainer 110 includes a ring-shaped retainer base 110a, screw holes 110b provided in the retainer base 110a through which the screws 112 pass, and radially extending from the outer edge of the retainer base 110a. It has a projecting piece 110c that protrudes outward, and a plurality of (three) notches 110d that are recessed radially inward from the outer edge of the retainer base 110a on the side facing the projecting piece.
Each screw hole 110b is arranged so as not to be rotationally symmetrical with respect to the center of the retainer base 110a. A plurality of screw hole portions 52m for receiving the screws 112 are formed in the front end portion of the inner cylindrical portion 52g. Such non-rotationally symmetrical arrangement of the screw holes 110b and the screw hole portions 52m prevents the retainer 110 from being mounted in the wrong orientation.
The projecting piece 110c is positioned within the rotation-permitting concave portion 54e of the mode switching ring 54 when viewed in the circumferential direction.
Notches 110d are evenly spaced circumferentially within a predetermined arc. A radially inward bulging portion of the leaf spring 114 can enter any one of the notches 110d.
Regarding the mode switching ring 54, when the leaf spring 114 enters the center notch 110d (refer to FIG. 11) against the urging force of the leaf spring 114 and is turned to the left when viewed from behind, the leaf spring 114 is in the right notch 110d (left state, see FIG. 40). At this time, the projecting piece 110c is positioned at the end of the rotation allowing recess 54e, and further leftward rotation is restricted by the rotation restricting rib 54d. Similarly, when turned to the right from the central state, the leaf spring 114 enters the left notch 110d (right state), and further rightward rotation is restricted.

As also shown in FIGS. 25 and 27, a plurality (five) of steel balls 120 as sliding members are provided between the mode switching ring 54 and the clutch ring 53 .
Five recessed portions 54g recessed forward from the rear surface of the mode switching ring base portion 54a are arranged at regular intervals in the circumferential direction. A ball 120 is placed in each recess 54g via a steel disk 122. As shown in FIG. On the other hand, a ring-shaped groove 53e is formed in the front surface of the clutch ring base portion 53a, and a steel washer 124 is inserted in the groove 53e. A rear portion of each ball 120 contacts a washer 124 .
When the mode switching ring 54 and the clutch ring 53 rotate relatively, each ball 120 rolls between the disk 122 and the washer 124, and the friction between the mode switching ring 54 and the clutch ring 53 is reduced.

As shown in FIGS. 11, 30, and 36 to 39, when the mode switching ring 54 is in the central state or the right state, the portions of the cam portion 54b other than the cam concave portion 54c are aligned with the respective cam protrusions of the support ring 100. As shown in FIGS. 100b, and the support ring 100 is positioned behind. Then, the pin holder 102 is positioned rearward, and each internal gear lock pin 106 enters between the projections 82c in the radial direction outside the third-stage internal gear 82 and in the circumferential direction. Each of these internal gear lock pins 106 prevents rotation of the third-stage internal gear 82 by contacting the side surface of the projecting portion 82c.
On the other hand, as shown in FIGS. 40 to 42, when the mode switching ring 54 is in the left state, the cam protrusions 100b enter the cam recesses 54c and the support ring 100 is positioned forward. Then, the pin holder 102 is positioned forward, and each internal gear lock pin 106 is retracted from the radially outer side of the internal gear 82 of the third stage. Therefore, each internal gear lock pin 106 does not hinder the rotation of the third-stage internal gear 82 . Therefore, the third-stage internal gear 82 starts to rotate with a torque corresponding to the rotational position of the clutch ring 53, and the clutch operates (clutch mode).
Each pin holder coil spring 104 urges the support ring 100 via the pin holder 102 to promote the entry of each cam protrusion 100b into the cam recess 54c. When the mode switching ring 54 is rotated from the left state to another state, the cam protrusions 100b are separated from the cam recesses 54c against the biasing force of the pin holder coil springs 104, and the pin holder 102 is positioned backward.

As also shown in FIG. 28(a), rollers 130 are arranged in pairs facing each other (right and left in the figure) between the protrusions 86c of the third stage carrier 86, respectively.
Lock cams 132 are arranged in the other pair (upper and lower in the drawing). The lock cam 132 has a cylindrical portion 132a and a pair of projecting pieces 132b projecting radially outward from the top and bottom of the cylindrical portion 132a. there is The central hole in the cylindrical portion 132 a of the lock cam 132 and the rear portion 55 d of the spindle 55 are spline-connected, and the lock cam 132 is integrated with the spindle 55 . The lock cam 132 rotates together with the third stage carrier 86 via each projection 86c.
The front side of the lock cam 132 is covered with a cylindrical lock ring 134 . The lock ring 134 is fixed inside the inner tubular portion 52 g of the gear housing 52 . The lock ring 134 includes a cylindrical lock ring base portion 134a, an inner flange 134b protruding inward from the inner surface of the front end portion of the lock ring base portion 134a, an outer flange 134c protruding outward from the outer surface of the rear end portion of the lock ring base portion 134a, and a lock. It has a plurality of (three) projections 134d that project radially outward from the side surface of the ring base 134a and further project forward, and are arranged at regular intervals in the circumferential direction. The rollers 130, the lock cams 132, and the projecting bodies 86c of the third stage carrier 86 are positioned behind the inner flange 134b. The projecting portion 134d enters the inner surface of the inner cylindrical portion 52g of the gear housing 52 formed in a corresponding shape, thereby fixing the lock ring 134 so as not to rotate.

15 to 18 and 26, the spindle 55 includes a spindle rear bearing 138 arranged on the front side of the lock ring 134 and a spindle front bearing 140 arranged radially outside the front step portion 55b. is held so as to be movable back and forth and rotatable around the axis.
The front spindle bearing 140 is arranged outside the front step portion 55 b of the spindle 55 .
A spindle coil spring 144, which is an elastic body, is provided between the spindle front bearing 140 and the spindle flange 55a. The rear surface of the spindle flange 55a and the spindle coil spring 144 have a tapered shape that gradually widens forward.
On the other hand, a clip 146 that presses (the front surface of the outer ring of) the spindle rear bearing 138 is inserted in a groove provided on the inner surface of the inner cylindrical portion 52 g of the gear housing 52 .

14, 16 to 18, 19, 20 and 22, a vibration mechanism 150 is arranged between the spindle front bearing 140 and the clip 146. As shown in FIGS. The vibrating mechanism 150 has a first vibrating cam 152 and a second vibrating cam 154 each having a ring shape and held by the intermediate stage portion 55 c of the spindle 55 .
A first cam surface 152b having a plurality of cam teeth is formed on the rear surface of a cylindrical first oscillating cam base portion 152a of the first oscillating cam 152 . The first oscillating cam 152 is integrally fixed to the spindle 55 by a circlip 156 fixed to the outside of the front end portion of the middle step portion 55 c of the spindle 55 . The spindle 55 is normally urged by the spindle coil spring 144 to the forward position where the circlip 156 contacts (the inner ring of) the spindle front bearing 140 .
A second cam surface 154b having a plurality of cam teeth is formed on the front surface of the ring-shaped second oscillating cam base 154a of the second oscillating cam 154 . A plurality (three) of claws 154c protruding rearward are provided at equal intervals in the circumferential direction on the rear surface of the second vibration cam base 154a. The second oscillating cam 154 is inserted into the spindle 55 without being fixed in the circumferential direction.
A ball retaining washer 160 , a plurality of steel balls 162 and a ball receiving washer 164 are provided between the second vibrating cam 154 and the clip 146 .
As also shown in FIG. 22, the ball retaining washer 160 is adjacent to the rear surface of the second oscillating cam base 154a. The ball holding washer 160 has a bowl shape with an inner peripheral portion as a front end and an outer peripheral portion as a rear end.
As also shown in FIG. 23, the ball receiving washer 164 has a plurality of (three) protrusions 164b that project radially outward from a ring-shaped ball receiving washer base 164a and that are arranged at regular intervals in the circumferential direction. , and constricted portions 164c respectively arranged between the convex portions 164b in the circumferential direction. The ball receiving washer 164 is prevented from rotating by the protrusions 164b entering recesses 52n provided on the inner surface of the inner cylindrical portion 52g of the gear housing 52. As shown in FIG.
At least one of the circlip 156 , the ball retaining washer 160 , the ball 162 and the ball receiving washer 164 may be included in the vibration mechanism 150 .

As also shown in FIGS. 15 to 24, a vibration switching ring 170 is provided inside the cam portion 54b of the mode switching ring 54 in the radial direction. On the rear side of the vibration switching ring 170, a set (three pieces) of vibration switching levers 172 having a one-third arc shape of the entire circumference is provided. A washer 174 is provided behind the vibration switching lever 172 .
The vibration switching ring 170 has a plurality of (three) projections 170b, which are arranged at equal intervals in the circumferential direction and protrude radially outward from the front end of a cylindrical vibration switching ring base 170a, and a vibration switching ring base. A plurality of (three) trapezoidal cam recesses 170c recessed forward from the rear end of 170a are arranged at the same positions as the projections 170b in the circumferential direction. Each protrusion 170b is in a corresponding recess 54h (see FIG. 13) provided at the rear of the cam portion 54b of the mode switching ring 54, and the vibration switching ring 170 is integrated with the mode switching ring 54. Rotate.
The vibration switching lever 172 includes a vibration switching lever base 172a having a U-shaped cross section that opens forward, and a protrusion 172b that protrudes forward in a shape corresponding to the cam recess 170c in the vibration switching lever base 172a (Figs. 21, etc.), and a vibration switching claw 172c (see FIGS. 22, 23, etc.) projecting radially inward and rearward from the central portion of the radially inner outer surface of the vibration switching lever base 172a. Each vibration switching lever 172 is provided with a plurality of (three) radial holes 52o (through holes, see FIG. 15) that are circumferentially equally spaced in the central portion of the inner cylindrical portion 52g of the gear housing 52 in the longitudinal direction. The vibration switching claw 172c is placed radially outward of the inner cylindrical portion 52g. The vibration switching lever 172 is arranged inside the support ring 100 .
22 and 23, each vibration switching pawl 172c is positioned radially outside the constricted portion 164c of the ball receiving washer 164. As shown in FIGS. That is, the ball receiving washer 164 has a constricted portion 164c that avoids each vibration switching claw 172c.
Further, each vibration switching claw 172c can advance and retreat between claws 154c projecting rearward on the rear side of the second vibration cam base 154a.

Between the three holes 52o in the inner cylindrical portion 52g of the gear housing 52 and adjacent to the six recessed portions 52k in the circumferential direction, pin holes 52p extending in the front-rear direction are respectively opened (Fig. 21, FIG. 27, etc.). A pin 180 is inserted into each pin hole 52p from behind. The front portion of each pin hole 52p is enlarged with respect to the rear portion, and between the enlarged portion and the front portion of each pin 180, a coil spring 182 for the vibration switching lever, which is an elastic body, is inserted. The front end of each vibration switching lever coil spring 182 is in contact with the rear washer 174 of each vibration switching lever 172 . Each vibration switching lever coil spring 182 biases the washer 174 and each vibration switching lever 172 forward.
As shown in FIGS. 22 and 23, when the mode switching ring 54 is in the center or left state, the rear end of the vibration switching ring base 170a, other than the cam recess 170c, rises from each vibration switching lever 172. As shown in FIGS. Each vibration switching lever 172 is positioned rearward in contact with the front end of the portion 172b. Then, each vibration switching claw 172c is positioned rearward and separated from between the claws 154c of the second vibration cam 154, and each vibration switching claw 172c rotates the second vibration cam 154 so that the rotation becomes possible. allow. When the spindle 55 rotates, the first vibrating cam 152 rotates integrally, and the second vibrating cam 154 also rotates appropriately via the first cam surface 152b and the second cam surface 154b. Since it is inserted into 55 and allowed to rotate, no vibration occurs.
On the other hand, as shown in FIG. 38, when the mode switching ring 54 is in the right state, the projections 172b corresponding to the respective cam recesses 170c enter, and the respective vibration switching levers 172 are positioned forward. Then, each vibration switching claw 172c is positioned forward and enters between the claws 154c of the second vibration cam 154 to block the second vibration cam 154 from rotating. When the spindle 55 rotates, the first oscillating cam 152 rotates integrally, whereas the second oscillating cam 154 does not rotate. The spindle 55 rotates in contact with the surface 154b, and axial vibration is generated in the spindle 55 (vibration mode).
When each vibration switching lever 172 is positioned forward, the rear end portion of the vibration switching ring base portion 170a relatively enters the vibration switching lever base portion 172a. The degree of contact with each vibration switching lever 172 increases. Therefore, when vibration occurs, the portion in front of each vibration switching lever 172 (inside the inner cylindrical portion 52g of the gear housing 52) is ensured to be closed and dustproof. Grease leakage is prevented.
Further, each vibration switching lever 172 is urged forward by the vibration switching lever coil spring 182, thereby promoting the entry of each protuberance 172b into the cam recess 170c. When the mode switching ring 54 is rotated from the right state to the other state, each protuberance 172b is separated from the cam recess 170c against the biasing force of the coil spring 182 for each vibration switching lever, and each vibration switching lever 172 is moved. located behind.

An operation example of such an electric vibration driver drill 1 will be described.
When an operator grips the grip portion 6 and pulls the switch lever 8, power is supplied from the battery 32 to the motor 10 by switching in the switch body portion 9, and the rotor 41 (motor shaft) rotates.
The rotation of the motor shaft causes the fan 44 to rotate. Air flow (wind) from the intake port 20c is generated by the exhaust from the fan 44 to each exhaust port 22a. Such air cools the motor 10 and other mechanisms within the housing 2 .

The rotational force of the motor shaft is reduced by the gear assembly 12 having a three-stage speed reduction mechanism, transmitted to the spindle 55, and transmitted to a bit such as a drill or driver attached to the chuck 14. FIG.
The intermediate planetary gear mechanism 70 of the gear assembly 12 operates in high speed mode or low speed mode according to the position of the speed switching lever 79 .

Furthermore, three operation modes can be selected according to the rotational position of the mode switching ring 54 .
That is, when the mode switching ring 54 is in the left state, the clutch mode is selected, and when torque corresponding to the rotational position of the clutch ring 53 is applied to the spindle 55, the front planetary gear mechanism 80 generates idle rotation and disengages the clutch. (Stop torque transmission). The screw tightening is advanced by the driver bit, and when the screw is completely inserted and a large torque is applied, the spindle 55 idles and the screw tightening is completed.
On the other hand, when the mode switching ring 54 is in the right state, the vibration mode is selected, each vibration switching lever 172 locks the rotation of the second vibration cam 154, and the retraction of the spindle 55 during rotation causes the first cam surface 152b to move. and the second cam surface 154b rub against each other, causing the spindle 55 to vibrate in the axial direction.
On the other hand, when the mode switching ring 54 is in the central state, the internal gear 82 of the front planetary gear mechanism 80 is fixed and the rotation of the second vibration cam 154 is permitted, so that the clutch does not operate and vibration does not occur. It becomes a drill mode that does not occur. In drill mode, the spindle 55 is rotated without declutching, and when the operator mounts the drill bit and proceeds to drill, the spindle 55 continues to rotate regardless of the load on the spindle 55 .

The above-described electric vibration driver drill 1 includes a housing 2 (gear housing 52), a mode switching ring 54 (first ring) and a clutch ring 53 (second ring) rotatably mounted on the housing 2, and each ball 120 (sliding member) arranged between the mode switching ring 54 and the clutch ring 53 . Therefore, the friction between the mode switching ring 54 and the clutch ring 53 is reduced, and the mode switching ring 54 and the clutch ring 53 are easily rotated.
Also, since the sliding members are the balls 120, the sliding members can be arranged more easily than in the case of cylindrical bearings.
Furthermore, discs 122 are interposed between the mode switching ring 54 and the balls 120 , and washers 124 are interposed between the clutch ring 53 and the balls 120 . Therefore, compared to the case where each ball 120 directly contacts the mode switching ring 54 or the clutch ring 53 , the rotation of each ball 120 is smoother, and the life of each ball 120, mode switching ring 54 and clutch ring 53 is longer. become longer.

Further, the electric vibration driver drill 1 can operate the housing 2 (gear housing 52), the vibration mechanism 150 and the clutch mechanism 99 respectively arranged inside the housing 2, and the vibration mechanism 150, and can rotate to the housing 2. a mode switching ring 54 (vibration switching ring) held in the housing 2, a clutch ring 53 (clutch switching ring) capable of operating the clutch mechanism 99 and rotatably held in the housing 2, the mode switching ring 54 and the clutch ring , each ball 120 positioned between the ball 53 and the ball 120 . Therefore, the friction between the mode switching ring 54 and the clutch ring 53 is reduced, and the mode switching ring 54 and the clutch ring 53 are easily rotated.
Furthermore, the mode switching ring 54 controls whether or not the spindle 55 (output shaft) is vibrated by the vibrating mechanism 150 depending on whether or not it is in the vibrating mode (right state). is operated by changing the rotational position. Therefore, the mode switching ring 54 and the clutch ring 53, which are easy to rotate, make it easier to command the presence or absence of vibration and the clutch actuation torque.

In addition, the electric vibration driver drill 1 includes a motor 10, a planetary gear 84 driven by the motor 10, an internal gear 82 that meshes with the planetary gear 84, and an internal gear lock pin that prevents rotation of the internal gear 82. 106 and a plurality of pin holder coil springs 104 for urging the internal gear lock pin 106 , and the central axis of the plurality of pin holder coil springs 104 coincides with the central axis of the internal gear lock pin 106 . are arranged in the circumferential direction. Therefore, in order to allow the coil spring to press the internal gear lock pin 106 as in the conventional case where the coil spring is mounted on the internal gear lock pin 106 with their central axes aligned, the internal gear lock is provided. There is no need to increase the diameter of the front end of the pin 106, the diameter of the entire internal gear lock pin 106 can be reduced, and each internal gear lock pin 106 and the housing 2 that accommodates them can be made compact in the radial direction. In addition, by providing a plurality of pin holder coil springs 104, the individual pin holder coil springs 104 can be reduced in size while ensuring the correct movement of the internal gear lock pin 106 in the forward and backward movement, and the housing 2 for accommodating them can be reduced. becomes radially compact.
A plurality of internal gear lock pins 106 are provided. As a result, the internal gear lock pin 106 becomes smaller in the radial direction while the internal gear lock pin 106 prevents the rotation of the internal gear 82 from being prevented. Directionally compact.
Furthermore, a plurality of pin holder coil springs 104 are arranged radially inward of the internal gear lock pin 106 . Therefore, the pin holder coil springs 104 are not positioned radially outward of the internal gear lock pin 106, and the electric vibration driver drill 1 becomes compact in the radial direction.
Furthermore, the internal gear lock pin 106 is held by the pin holder 102 , and a plurality of pin holder coil springs 104 bias the internal gear lock pin 106 via the pin holder 102 . Therefore, the radially compact electric vibration driver drill 1 is simply formed.
In addition, each clutch pin 96 that contacts the internal gear 82 and a washer 94 that contacts each clutch pin 96 are provided. Each spring holding part 102c to hold is arranged. Therefore, the washer 94 for the clutch mode and the rear portion of the pin holder 102 for the vibration mode and the drill mode overlap in the radial direction, making the electric vibration driver drill 1 compact in the front-rear direction. In the clutch mode, the washer 94 moves back and forth via each clutch pin 96. If a portion of the pin holder 102 is arranged radially inward of the movement range, compactness in the front and back direction is ensured. .
It also has clutch pins 96 that contact the internal gears 82 and washers 94 that contact the clutch pins 96. The washers 94 have valleys 94d through which the internal gear lock pins 106 pass. ing. Thus, each clutch pin 96 contacting internal gear 82 for clutch mode is enabled by washer 94, and each internal gear lock prevents rotation of internal gear 82 for vibration mode and drill mode. The pin 106 is arranged compactly in the radial direction by passing through the valley portion 94d.

It should be noted that the embodiments and modifications of the present invention are not limited to the embodiments and modifications described above, and for example, the following further modifications can be made as appropriate.
At least one of the disk 122 and the washer 124 may be omitted. The disk 122 may be arranged on the clutch ring 53 side, and the washer 124 may be arranged on the mode switching ring 54 side. Disks 122 may be arranged on both sides, and washers 124 may be arranged on both sides.
Also, instead of the ball 120, or together with the ball 120, a resin washer (sliding member) having smooth front and rear surfaces may be used. When balls 120 are not used, mode switching ring 54 and clutch ring 53 slide against the smooth surfaces of the washers to reduce friction.
The arrangement of these may be changed, for example, the mode switching ring 54 may be positioned behind the clutch ring 53 . At least one of the mode switching ring 54 and the clutch ring 53 may be mounted on the housing 2 or replaced with another ring that can be operated by the operator.
Clutch mechanism 99 may be an electronic clutch. The vibration mechanism 150 may electrically generate vibration. The vibrating mechanism 150 may be omitted and an electric driver drill without a vibrating mode may be used. The clutch mechanism 99 may be omitted, and a vibrating drill without a clutch mode may be used. The drill mode may be omitted, and the vibrating driver without the drill mode may be used.

The internal gear lock pin 106 may be held by the pin holding portion 102d in another form such as press-fitting the projection into the hole. Other forms of holding, press-fitting, etc. may similarly be changed as appropriate.
The fan 44 may be arranged forward of the stator 40 .
Battery 32 can be any lithium ion battery from 18 to 36V, such as 14.4V, 18V (20V maximum), 18V, 25.2V, 28V, 36V, etc. Lithium-ion batteries can be used, as well as other types of batteries.
Gear housing 52 may be retained within main body housing 20 .
The number of sections of the housing 2, the number of planetary gears, the number of stages of the speed reduction mechanism, the number of various balls, the number of rollers 130, the number of various protrusions (protrusions, protrusions, protrusions, etc.), various pins , the number of various springs, and/or the number of various screws may be increased or decreased with respect to the above numbers. The materials of various members may be changed, for example, a ball made of steel may be made of resin. The form of various operating parts such as the form of the switch of the switch lever 8 may be changed. The arrangement of various members or parts may be changed, such as the spring holder 90 of the clutch mechanism 99 being arranged radially inside the pin holder 102 for locking the internal gear 82 . The shape of various members may be changed, for example, the disk 122 may be a regular polygonal plate.
Also, the direction of the output shaft (tip tool holding portion) is different from the direction of the power portion (at least one of the direction of the motor shaft of the motor and the transmission direction of the mechanism that transmits the rotational force) (approximately 90 degrees). The present invention may be applied to angle power tools.
Furthermore, non-rechargeable (battery driven) vibration driver drills, including those driven by commercial power, or other power tools other than vibration driver drills, or gardening tools, including cleaners, blowers, or garden trimmers For example, the present invention may be applied.

1... Electric vibration driver drill (electric tool), 2... Housing, 10... Motor, 82... Internal gear, 84... Planetary gear, 94... Washer (clutch washer), 94d... Valley, 96... Clutch pin, 102... Pin holder, 102c... Spring holding part (elastic body holding part), 104... Coil spring for pin holder (elastic body), 106... Internal gear lock pin.

Claims (8)

a motor;
a planetary gear driven by the motor;
an internal gear meshing with the planetary gear;
a plurality of internal gear lock pins that prevent rotation of the internal gear by entering radially outward of the internal gear;
a plurality of elastic bodies for biasing each of the internal gear lock pins;
and
The power tool, wherein the plurality of elastic bodies have central axes different from the central axis of each of the internal gear lock pins and are arranged in a circumferential direction. The power tool according to claim 1 , wherein a plurality of said elastic bodies are arranged radially inward of each said internal gear lock pin. Each said internal gear lock pin is held by a pin holder,
3. The power tool according to claim 1 , wherein the plurality of elastic bodies bias the internal gear lock pin through the pin holder. a clutch pin that contacts the internal gear;
a clutch washer contacting the clutch pin;
and
4. The power tool according to claim 3 , wherein an elastic body holding portion for holding the elastic body in the pin holder is arranged radially inward of the clutch washer. a clutch pin that contacts the internal gear;
a clutch washer contacting the clutch pin;
and
The power tool according to any one of claims 1 to 4 , wherein the clutch washer has a valley through which each of the internal gear lock pins passes. The internal gear has a plurality of protrusions that protrude radially outward and are arranged in a circumferential direction,
each said internal gear lock pin enters between said protrusions in the circumferential direction
The power tool according to any one of claims 1 to 5, characterized in that: a motor;
a planetary gear driven by the motor;
an internal gear meshing with the planetary gear;
an internal gear lock pin that prevents rotation of the internal gear;
a plurality of elastic bodies for biasing the internal gear lock pin;
a pin holder that holds the internal gear lock pin;
a clutch pin that contacts the internal gear;
a clutch washer contacting the clutch pin;
and
The plurality of elastic bodies have central axes different from the central axis of the internal gear lock pin, are arranged in a circumferential direction , and bias the internal gear lock pin via the pin holder,
An electric power tool , wherein an elastic body holding portion for holding the elastic body in the pin holder is disposed radially inward of the clutch washer . a motor;
a planetary gear driven by the motor;
an internal gear meshing with the planetary gear;
an internal gear lock pin that prevents rotation of the internal gear;
a plurality of elastic bodies for biasing the internal gear lock pin;
a clutch pin that contacts the internal gear;
a clutch washer contacting the clutch pin;
and
the plurality of elastic bodies have central axes different from the central axis of the internal gear lock pin and are arranged in a circumferential direction;
The power tool , wherein the clutch washer has a valley through which the internal gear lock pin passes .

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