JP2014240114A - Electric rotary tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric rotary tool which is easily formed and enables easy handling.SOLUTION: An oil pulse driver 1 includes: a motor 10; a planetary gear mechanism 12 driven by the motor 10; a shaft 14 which is connected with the planetary gear mechanism 12 and is rotationally driven by the planetary gear mechanism 12; and a unit case 22 housing the planetary gear mechanism 12. The unit case 22 is formed by a resin. Further, a cover 24 is provided at an outer periphery of the unit case 22. Furthermore, a motor housing 20 for housing the motor 10 is provided. Unit case attachment ribs 20c, 20c, a step part 20d, and a rib 20e (fitting parts) are provided at the motor housing 20, and unit case ribs 22a, 22a (fitted parts) are provided at the unit case 22. The fitted parts are fitted into the fitting part.

Description

  The present invention relates to an electric rotary tool that rotates a bit or the like by an electric driving force.

As shown in Patent Document 1 below, there is known a hydraulic torque wrench provided with a transmission device having a cylinder filled with hydraulic oil in an exterior portion. The cylinder is rotated by a drive motor via a rear planetary gear mechanism.
In such a hydraulic torque wrench, the exterior portion is made of metal.

JP 2008-44080 A

In the above-described hydraulic torque wrench, the exterior part is formed of metal, so that it is excellent in strength, but it takes time and labor to combine with processing and internal members, and causes an increase in the overall weight. There is room for improvement in ease of handling.
The main object of the present invention is to provide an electric rotary tool that is easier to form and handle.

In order to achieve the above object, the invention according to claim 1 is directed to a motor, a reduction gear unit driven by the motor, and an output unit connected to the reduction gear unit and driven to rotate by the reduction gear unit. And an electric rotary tool having a case for accommodating the reduction gear portion, wherein the case is made of resin.
The invention according to claim 2 is the above invention, wherein a cover is provided on an outer periphery of the case.
The invention according to claim 3 is the above invention, wherein a housing for housing the motor is provided, a fitting portion is provided in the housing, a fitting portion is provided in the case, and the fitting portion and the covered portion are provided. The fitting portion is fitted.
The invention according to claim 4 is the above invention, wherein the cover is made to hold a damper.
The invention according to claim 5 is the above invention, wherein the output section is connected to an oil unit capable of generating impact torque.
The invention according to claim 6 is the above invention, wherein a housing for housing the motor is provided, and the case is screwed to the housing.
The invention according to claim 7 is the above invention, wherein a housing for housing the motor is provided, and an impact mechanism portion is disposed inside the case.
According to an eighth aspect of the present invention, in the above invention, the case is prevented from being pulled forward by the front retaining portion of the housing and is prevented from rotating left and right. The gear part is characterized in that it is prevented from coming out backward by the rear retaining part of the housing.
The invention according to claim 9 is the above invention, wherein the cover is provided with a hole for fixing the damper adjacent to an engaging portion for stopping the rotation of the cover. It is.

  According to the present invention, it is possible to provide an electric rotary tool that is easier to form and handle.

It is a left view of the impact driver which concerns on this invention. It is a front view in FIG. It is a center longitudinal cross-sectional view in FIG. FIG. 4 is a partially enlarged view of the main body in FIG. 3. It is a cross-sectional view of FIG. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG.

Hereinafter, embodiments of the present invention and modifications thereof will be described with reference to the drawings as appropriate.
FIG. 1 is a left side view of a rechargeable oil pulse driver 1 which is an example of an electric rotary tool or a hammering tool, FIG. 2 is a front view of the oil pulse driver 1, and FIG. 4 is a partial enlarged view of the central longitudinal section of the oil pulse driver 1, FIG. 5 is a transverse sectional view of the main body 4 of the oil pulse driver 1, and FIG. FIG. 7 is a sectional view taken along line BB in FIG.
The oil pulse driver 1 has an outer housing 2 that forms an outer shell thereof. In FIG. 1, the left is the front.
The oil pulse driver 1 includes a cylindrical main body portion 4 having a central axis in the front-rear direction, and a grip portion 6 formed so as to protrude from the lower portion of the main body portion 4.
The grip portion 6 is a portion that is gripped by the user, and a trigger-type switch lever 8 that can be pulled with a fingertip by the user is provided on the upper portion of the grip portion 6. The switch lever 8 protrudes from the switch body 8a.

In the main body part 4 of the oil pulse driver 1, a motor 10, a planetary gear mechanism 12 as a reduction gear part, an oil unit 13 as a striking mechanism part, and a shaft 14 as an output part are accommodated coaxially in this order from the rear side. Has been.
The motor 10 is a drive source of the oil pulse driver 1, and its rotation is decelerated by the planetary gear mechanism 12, and then transmitted to the shaft 14 through an oil unit 13 that appropriately applies a blow to the rotation. The shaft 14 is a portion that rotates around an axis in response to a rotational impact force.

  The outer housing 2 includes a motor housing 20 (housing) extending from the rear portion of the main body portion 4 to the grip portion 6, a unit case 22 disposed in front of the upper portion of the motor housing 20, a cover 24, and a damper 26.

The motor housing 20 includes a half cylinder-shaped left motor housing 20a (left housing) and a right motor housing 20b (right housing). The left motor housing 20a and the right motor housing 20b are fixed to each other by screws 28, 28,... (FIGS. 3 and 4). The motor housing 20 in the main body 4 accommodates the motor 10.
On the upper front side of the motor housing 20 (the front lower part of the main body part 4), there are formed a light holding upper housing 20f arranged above the light 32, which will be described later, and a light holding lower housing 20h arranged below the light 32. Has been.

The unit case 22 (case) is made of resin, more specifically, made of synthetic resin. The unit case 22 is formed in a cylindrical shape (cylindrical shape) whose front portion is reduced in diameter relative to the rear portion.
The unit case 22 is attached in a state where its rear part enters the front part of the motor housing 20, and is connected to the motor housing 20. The front portion of the motor housing 20 is opened in a cylindrical shape (cylindrical shape).
Unit case ribs 22 a and 22 a projecting outward are provided inside the rear portion of the unit case 22.
On the other hand, on the front side or rear side of the unit case ribs 22a, 22a on the inner side of the front portion of the motor housing 20, unit case mounting ribs 20c, 20c projecting inward with respect to the periphery thereof are provided. Further, a step portion 20d is formed in front of the front unit case mounting rib 20c with an interval equivalent to the thickness of the front unit case rib 22a in the front-rear direction. The step portion 20d is formed such that the rear side extends radially outward with respect to the front side, and the rear inner diameter expands with respect to the front inner diameter. Further, a rib 20e is formed behind the rear unit case mounting rib 20c. The rib 20e protrudes inward with respect to the periphery of the rear unit case rib 22a with an interval equivalent to the thickness in the front-rear direction. .
The unit case mounting ribs 20c and 20c are arranged on the front side or the rear side of the unit case ribs 22a and 22a. The front unit case mounting rib 20c and the stepped portion 20d (fitting portion) are fitted with the front unit case rib 22a (fitting portion), and the rear unit case mounting rib 20c and the rib 20e The rear unit case rib 22a (fitting portion) is fitted between the fitting portions. The unit case ribs 22a and 22a are fitted on the front side or the rear side of the unit case mounting ribs 20c and 20c, so that the unit case 22 is fixed in front of the motor housing 20. The fitting portion and / or the fitted portion serves as a connection portion between the unit case 22 and the motor housing 20. In addition, the fitting part and / or the fitted part is a front retaining part that prevents the unit case 22 from coming forward (separated from the motor housing 20), and preventing the unit case 22 from rotating left and right with respect to the motor housing 20. It has become one of the.
Further, a step portion 20 i is formed inside the front end opening of the motor housing 20. The diameter on the rear side of the stepped portion 20i is larger than the diameter on the front side of the stepped portion 20i. Further, a step portion 22d is provided on a side surface of the unit case 22 and corresponding to the step portion 20i. The diameter of the rear side of the step part 22d is larger than the diameter of the front side of the step part 20i. The sizes of the stepped portions 20i and 22d are the same, and by combining them, the unit case 22 is prevented from coming off forward, and the unit case 22 is prevented from rotating left and right (the front retaining portion Another one).
Further, holes 22c and 22c for taking in air are provided on the left and right in the center of the unit case 22 (FIG. 5).
The unit case 22 accommodates the planetary gear mechanism 12 (other than the rear end portion) and the oil unit 13. In addition, a front portion of the planetary gear mechanism 12 and a rear portion of the oil unit 13 are disposed inside a portion where the motor housing 20 and the rear portion of the unit case 22 overlap each other.
The lower rear portion of the unit case 22 is provided with a concave portion 22e that is further recessed downward with respect to the front side portion (extension line thereof). Resin damper holes 22f and 22f are formed on the right and left sides of the recess 22e in the unit case 22 in the inward direction (FIG. 6). The lower side of each resin damper hole 22f is a protrusion 22g protruding outward (FIG. 6).
The inner wall portion (left pinching portion 20j) of the left motor housing 20a is in contact with the outer side of the left protrusion 22g, and the inner wall portion (right pinching portion) of the right motor housing 20b is in contact with the outer side of the right protrusion 22g. Part 20k) is in contact, and the lower rear part of the unit case 22 is sandwiched between the left sandwiching part 20j and the right sandwiching part 20k (FIG. 6).

The cover 24 has a tubular shape (cylindrical shape) with a front portion reduced in diameter relative to the rear portion. Damper holding ribs 24 a and 24 a projecting outward are provided above and below the front portion of the cover 24. A slit-like hole 24d for fixing the damper 26 is formed on the rear side of each damper holding rib 24a.
The lower part of the cover 24 is so formed as to correspond to the upper part of the switch lever 8 in the motor housing 20 (avoid this part), and the rear end of the lower part of the cover 24 is in front of the rear end of the upper part of the cover 24. Yes. The rear end surface (lower end surface) of the lower portion of the cover 24 is continuous with the upper surface of the light holding upper housing 20f of the motor housing 20, and is supported by the upper surface. That is, the cover 24 is held by the motor housing 20. Further, the cover 24 (lower part) is sandwiched between the left motor housing 20a and the right motor housing 20b. The light holding upper housing 20f of the motor housing 20 is disposed behind the connecting portion (unit case mounting rib 20c, stepped portion 20d, rib 20e, unit case rib 22a) of the unit case 22 and the motor housing 20. The cover 24 (lower part) is held between the light 32 and the unit case 22.
The cover 24 covers the outside of the front portion of the unit case 22, that is, the cover 24 is provided on the outer periphery of the unit case 22. The cover 24 is held on the outer periphery of the unit case 22 and covers the unit case 22. The front end portion of the unit case 22 protrudes forward from the front end of the cover 24, and the central portion of the unit case 22 is disposed inside the cover 24.
The front peripheral surface of the lower part of the unit case 22 is connected to the inner surface of the light holding upper housing 20f at the lower part of the motor housing 20. The inner surface of the light holding upper housing 20f of the motor housing 20 holds the lower part of the unit case 22, and in addition to holding the light 32, it also serves as one of the holding portions for holding the unit case 22. Yes. A rear end portion of the lower portion of the cover 24 is arranged inside the light holding upper housing 20f.
On the other hand, the rear peripheral surface of the lower part of the unit case 22 is held by the left and right unit case holding ribs 20g, 20g (another holding unit for holding the unit case 22). Each unit case holding rib 20g protrudes inward from the inner surface of the left motor housing 20a or the right motor housing 20b inward.
A groove-like engaging portion 24c corresponding to the shape of the upper portion of the light holding upper housing 20f is formed at the lower portion of the cover 24, and the engaging portion 24c and the light holding upper housing 20f are engaged with each other. 24 is prevented from coming off and rotation to the left and right is stopped (rotating stop portion, FIGS. 3 and 4). A lower hole 24d is disposed so as to be adjacent to the engaging portion 24c.
Further, left and right sides of the cover 24 are formed with projecting portions 24b and 24b that swell outward from other portions. Gaps 25 are formed between the inner surfaces of the protrusions 24 b and 24 b and the outer surface of the unit case 22. A hole 22c of the unit case 22 is disposed inside each protrusion 24b, and each hole 22c faces the corresponding gap 25.
Further, a slit-like shape is formed between the left and right of the front end of the upper portion of the motor housing 20 and the left and right of the rear end of the cover 24 (between the motor housing 20 and the unit case 22 on the left and right of the front of the main body 4). Front intake ports 27 are formed. The protrusions 24 b and 24 b of the cover 24 are disposed in front of the front intake ports 27 and 27.
Therefore, on the left side of the main body 4, the front intake port 27 forms a ventilation path W <b> 0 that allows ventilation between the cover 24 and the left motor housing 20 a. Further, on the left side of the main body 4, a ventilation path W <b> 1 is formed from the ventilation path W <b> 0 to the front side (hole 22 c) in the unit case 22 by the gap 25 (inside the protrusion 24 b). The ventilation path W1 is formed between the cover 24 (the inner surface) and the unit case 22 (the outer surface). The ventilation path W0 to the ventilation path W1 are continuous, and air can be passed from the outside to the front of the unit case 22. On the other hand, the ventilation paths W0 and W1 are similarly formed on the right side of the main body 4.
Further, a gap 29 is formed between the unit case 22 (the inner surface) and the oil unit 13 (the outer surface), and the ventilation path W2 is formed by the hole 22c and the gap 29. The ventilation path W2 is continuous with the ventilation path W1 through the holes 22c and 22c.
On the other hand, a gap is provided between the recess 22e of the unit case 22 and the planetary gear mechanism 12 (a lower outer surface of an internal gear 72 described later), thereby forming a ventilation path W3 through which air can flow. The ventilation path W3 communicates with the ventilation path W2.

The damper 26 has a ring shape exhibiting elasticity, and has grooves 26a and 26a having shapes corresponding to the damper holding ribs 24a and 24a on the inner upper and lower sides.
The damper 26 is placed on the outside of the front end portion of the unit case 22 protruding from the cover 24. Each groove 26 a of the damper 26 receives a corresponding damper holding rib 24 a, and the damper 26 is held by the cover 24.
The damper 26 is formed in a state in which a phosphorescent material is mixed, and exhibits a phosphorescence and can emit light in a dark place. Note that the front end of the unit case 22 slightly protrudes from the front end of the damper 26.
The unit case 22, the cover 24, the damper 26, and the front lower side of the motor housing 20 (the light holding upper housing 20 f and the light holding lower housing 20 h or its peripheral portion) are the outer shell of the front portion of the main body 4. .

A forward / reverse switching lever 30, which is a switch for switching the rotation direction of the motor 10, is located in the lower part (grip part 6) of the motor housing 20 and behind the switch lever 8 (upper side of the switch body part 8 a). 4 and the grip part 6 are provided so as to penetrate from side to side in the boundary region.
A light 32 that can irradiate the front is provided above the switch lever 8 and in front of the forward / reverse switching lever 30. A light holding upper housing 20f of the motor housing 20 is disposed above the light 32, and the light 32 is accommodated between the light holding upper housing 20f and the light holding lower housing 20h.
The light 32 is an LED, and is provided so as to overlap the switch lever 8 in the vertical direction. Since the light 32 is provided so as to overlap with the switch lever 8 in the vertical direction, the occurrence of a situation that prevents the irradiation of the light 32 without the user's finger or the like being positioned in the irradiation direction of the light 32 is prevented, The visibility when the light 32 is turned on can be improved. The unit case 22 has a recess (not shown) for holding the lead wire of the write 32.
The lower end portion of the grip portion 6 is a battery attachment portion 34 that mainly spreads forward with respect to the upper portion thereof, and is detachably attached to the lower portion of the battery attachment portion 34 by a slider 36 for moving the hook 35 up and down. A battery 37 is held. Here, the battery 37 is a lithium ion battery of 14.4 V (volts).
A control circuit board 38 is disposed inside the battery mounting portion 34. The control circuit board 38 is accommodated in a resin board case 39 having a flat box shape. The substrate case 39 is fixed inside the battery mounting portion 34 (between the lower end of the left motor housing 20a and the lower end of the right motor housing 20b). The control circuit board 58 is provided with six switching elements (not shown) and a microcomputer (not shown) that are provided corresponding to each drive coil 48 described later and switch the corresponding coil 48. The microcomputer controls the switching elements 44, 44,. The switching element may be mounted on a sensor substrate 44 described later.

The motor 10 is a brushless DC motor, and includes a stator 40, a rotor 42, and a sensor substrate 44.
The stator 40 has a plurality of (six) coils 48, 48... Wound around a stator core 45 via a front insulating member 46 and a rear insulating member 47. Further, a total of six coil connecting portions (not shown) as contact points for electrically connecting each drive coil 48 and the sensor substrate 44 are provided on the front peripheral edge of the front insulating member 46.
The rotor 42 is disposed around the rotor shaft 50 as a rotation shaft, a cylindrical rotor core 51 fixed around the rotor shaft 50, and the rotor core 51, and has a cylindrical shape and alternating polarities in the circumferential direction. It has the permanent magnet 52 changed into. The rotor core 51 and the permanent magnet 52 are disposed inside the stator core 45. A plurality of sensor permanent magnets (not shown) are arranged radially on the front side (sensor substrate 44 side) of the rotor 42. The rotor core 51, the permanent magnet 52, and the sensor permanent magnet are assembled (rotor assembly).
The sensor board 44 is electrically connected to each coil 48, the terminal part (battery 37) or the control circuit board 38 of the battery mounting portion 34 by lead wires (not shown), and controls the energization state of each coil 48. Thus, the rotation of the rotor 42 is controlled. Three magnetic sensors (not shown) are fixed to the rear surface of the sensor substrate 31. The sensor substrate 44 is attached to the front side of the front insulating member 46 by screws 54 and 54.
A cylindrical resin sleeve 55 is provided on the front side of the rotor core 51 in the rotor shaft 30. A bearing 56 in front of the rotor shaft 50 is provided in front of the resin sleeve 55. A pinion 57 is fixed to the front end of the rotor shaft 50 in front of the bearing 56.
A cooling fan 60 is attached to the rear portion of the rotor shaft 50 via a metal insert bush 59. The insert bush 59 is press-fitted, and the fixing force of the fan 60 to the rotor shaft 50 is high. The bearing 56 is arranged on a straight line connecting the centers of the upper center screw 28 of the main body 4 and the lower (center) screw 28 of the main body 4. Therefore, vibration of the rotor shaft 50 can be effectively suppressed.
Exhaust ports 61, 61... Formed of a plurality of small holes are formed in a radially outer portion of the fan 60 in the motor housing 20. Further, air inlets 62, 62,... Formed of a plurality of small holes are formed in the radially outer portions of the front insulating member 46 and the sensor substrate 44 in the motor housing 20. When the fan 60 is rotated together with the rotor shaft 50, external air is introduced into the motor housing 20 through the intake ports 62, 62... And discharged from the exhaust ports 61 and 61 through various members of the motor 10.
A bearing 64 behind the rotor shaft 50 is provided around the rear end portion of the rotor shaft 50. The bearing 64 is fixed inside the upper rear end of the motor housing 20 while being sandwiched between the left motor housing 20a and the right motor housing 20b.

A planetary gear mechanism 12 is disposed around the front end portion of the rotor shaft 50 and the pinion 57.
The planetary gear mechanism 12 includes an internal gear 72 having an internal tooth portion 72 c, a plurality of planetary gears 74, 74... Having external tooth portions 74 a meshing with the internal tooth portion 72 c of the internal gear 72, and each planetary gear 74. Each pin 76 and a carrier 77.

The internal gear 72 has a cup-shaped internal tooth holding portion 72a that opens forward.
The internal tooth holding part 72a has a bearing holding part 72b protruding rearward in a cylindrical shape with respect to the periphery at the rear part.
Further, an inner tooth portion 72c protruding inward from the front portion is provided at the rear portion of the cylindrical inner surface of the inner tooth holding portion 72a. In the internal tooth portion 72c, internal teeth that mesh with the planetary gears 74, 74,... Are formed, and the internal tooth portion 72c is held by the internal tooth holding portion 72a. In addition, a bearing holding portion 72d is formed in the front portion of the inner surface of the cylindrical surface of the internal tooth holding portion 72a (inside the opening of the internal tooth holding portion 72a). The bearing holding portion 72d is formed so as to be recessed outward from the root of the inner tooth in the inner tooth portion 72c, and has a diameter increased with respect to the rear portion of the cylindrical inner surface of the inner tooth holding portion 72a.
As shown in FIG. 7 in particular, the rear portion of the internal tooth holding portion 72a has a bearing holding portion 72b at the center when viewed from the rear, and ribs 72e, 72e,. Has been.
The inside of the bearing holding portion 72b is a hole in the front-rear direction that penetrates to the inside of the internal tooth portion 72c, and the tip portion of the rotor shaft 50 and the rear portion of the pinion 57 are disposed in the hole. Further, the bearing 56 in front of the rotor shaft 50 is held in the rear portion (inside the opening) of the hole in the bearing holding portion 72b.
The bearing holding portion 72b and the ribs 72e, 72e,... Are held by internal gear fixing ribs 78, 78,. Each of the internal gear fixing ribs 78 protrudes to a position reaching the outer surface of the bearing holding portion 72b or the outer surfaces of the ribs 72e, 72e,. Internal gear fixing ribs 78 and 78 (previous internal gear fixing ribs 78 and 78) reaching the internal tooth holding portion 72a are formed integrally with the unit case 22 fixing rib 20e. Ventilation holes 78a and 78a are opened at the bases of the lower internal gear fixing ribs 78 and 78 (FIGS. 3, 4, and 7). Since ventilation is possible at the ventilation openings 78a and 78a outside the internal gear 72, the ventilation openings 78a and 78a are also included in the ventilation path W3 outside the internal gear 72.
The internal gear 72 is prevented from coming out rearward by the internal gear fixing ribs 78 sandwiching the side portion and the rear portion thereof. The tip of each internal gear fixing rib 78 is a sandwiching portion 78b (FIG. 7).
The rear portion of the unit case 22 (the portion on the rear side of the front unit case rib 22a) is connected to the motor housing 20 (the inner surface of the fitting portion and the front end surface of the unit case mounting rib 20c) and the internal gear 72 (the inner tooth holding portion 72a). The outer surface of the
On the other hand, the front end of the internal gear 72 (the front surface of the bearing holding portion 72d of the internal tooth holding portion 72a) is in contact with the step portion 22b formed on the inner surface of the unit case 22 (FIG. 5). The step portion 22b is formed such that the inner diameter on the rear side is larger than the inner diameter on the front side, and the front unit case rib 22a (or the fitting portion between the front unit case mounting rib 20c and the step portion 20d). It is arrange | positioned radially inward.
A ring-shaped recess 72f that is recessed rearward with respect to the surrounding surface is provided on the vertical inner surface of the internal tooth holding portion 72a of the internal gear 72. On the inner side of the internal tooth holding portion 72a, grease is appropriately applied to ensure lubrication for each planetary gear 74. However, since the grease can be stored in the recess 72f, lubrication is performed with a longer period until the grease is cut. Occurrence of a shortage can be prevented, and the number of grease replenishments can be reduced to improve the maintainability. In addition, the surface area of the internal gear 72 can be increased by installing the recess 74 as compared with the case where the recess 74 is not installed, and heat generated during operation can be radiated more efficiently.

Each planetary gear 74 is provided around the pin 76 so as to be rotatable around the corresponding pin 76. An outer tooth portion 74 a of each planetary gear 74 meshes with the teeth of the pinion 57.
On the front side of each planetary gear 74, a plate-like carrier 77 extending in the vertical and horizontal directions is arranged. The carrier 77 rotatably receives the front portion of each pin 76. A spline hole is formed in the center of the carrier 77.
The carrier 77 is disposed on the inner peripheral side (inward in the radial direction) of the internal gear 72.
When the rotor shaft 50 rotates and the pinion 57 rotates, each planetary gear 74 revolves along with its rotation according to the internal teeth 72c of the internal gear 72, and the carrier 77 decelerates via each pin 76 due to the revolution of each planetary gear 74. Rotated up.

The oil unit 13 includes a cup-shaped front oil case 80 opened rearward, a cup-shaped rear oil case 81 opened forward, screws 82 and 82, an inner ring 83 formed of an elastic material, A ring-shaped plate 84 for pressing the ring 83 from the rear, a cam 85, balls 86 and 86, blades 88 and 88, a middle seal ring 90 and a rear seal ring 92, an output adjusting mechanism 94, and a seal ring 100 And a ring 102.
The shaft 14 (rear part), the shaft bearing 104, and the front seal ring 105 can be treated as components of the oil unit 13.

The front oil case 80 has a cylindrical rib 80a that protrudes rearward from the front rear surface in a cylindrical shape. Further, a stepped portion 80b whose diameter is increased on the rear side with respect to the front side is formed on the inner surface of the side portion of the front oil case 80.
A ring 83 is disposed outside the cylindrical rib 80a and inside the side surface of the front oil case 80. The ring 83 is a ring-shaped member formed of resin (more specifically, synthetic resin). Inside the ring 83, a gas 83a (air) is sealed.
A plate 84 is arranged on the rear side of the ring 83, the cylindrical rib 80a, and the rear side of the stepped portion 80b. The plate 84 has gap portions 84a and 84a at positions facing each other (up and down in FIGS. 3 and 4), and the periphery of the ring 83 and the rear portion of the plate 84 communicate with each other by the gap portions 84a. .
Screw holes for the screws 82 and 82 are formed in portions of the front oil case 80 located in front of the gaps 84a and 84a.

The rear oil case 81 has a cylindrical side wall part 81a, a central part 81b on the rear side of the side wall part 81, and a rear part 81c on the rear side of the central part 81b.
The side wall portion 81 a is put in contact with the rear opening of the front oil case 80. An intermediate seal ring 90 and a rear seal ring 92 are disposed between the side wall portion 81 a and the front oil case 80.
Bumped portions 96 and 96 that protrude inward with respect to the other inner surface (cylindrical surface) are provided at positions of the inner surface of the side wall portion 81a facing each other (left and right in FIG. 5).
The central part 81b closes the rear end of the side wall part 81a. The outer surface of the center part 81b is cylindrical, The diameter is made smaller than the outer diameter of the side wall part 81a. That is, at the boundary between the side wall portion 81a and the central portion 81b, a step is formed in which the rear is reduced in diameter and recessed.
An oil unit bearing 97 that rotatably supports the rear oil case 81 (oil unit 13) is disposed outside the center portion 81b. The outer surface part (rear part) of the oil unit bearing 97 is fitted into the bearing holding part 72 d, and the oil unit bearing 97 is held by the bearing holding part 72 d of the internal tooth holding part 72 a in the internal gear 72. An oil unit bearing 97 (first bearing), an internal tooth holding portion 72a, a bearing 56 (second bearing) in front of the rotor shaft 50, and a rear oil case 81 (central portion 81b and rear portion 81c) A closed space is formed in the gear 72, and the oil unit bearing 97 and the bearing 56 are components of the closed space (outer).
The rear part 81c is formed so as to protrude in a cylindrical shape rearward from the rear surface of the central part 81b. The rear part 81c is reduced in diameter from the central part 81b. The outer diameter of the rear portion 81 c is equal to the diameter of the spline hole of the carrier 77. A spline groove that meshes with a spline hole of the carrier 77 is formed on the outer surface of the rear portion 81c, and the carrier 77 and the rear portion 81c are formed so as to be rotationally locked to each other. In addition, the rotation locking structure in the carrier 77 and the rear part 81c may be any structure such as a hexagonal hole (polygonal hole) and a hexagonal column (polygonal column) instead of the spline structure.

The rear portion of the shaft 14 is placed inside the front oil case 80 and the rear oil case 81. The shaft 14 is connected to the oil unit 13.
The hole at the center of the plate 84 and the inner surface of the cylindrical rib 80a are in contact with the outer surface of the rear portion of the shaft 14. On the front side of the cylindrical rib 80a, a seal ring 100 and a ring 102 are provided in contact with the outer surface of the shaft 14 in the central hole.
A shaft bearing 104 that rotatably supports the shaft 14 is disposed on the front side of the front oil case 80. The shaft bearing 104 is attached inside the front portion of the unit case 22. Further, a front seal ring 105 is disposed on the front side of the shaft bearing 104. The front seal ring 105 is in contact with the outer surface of the shaft 14. The front seal ring 105 is attached inside the front portion of the unit case 22.
Inside the shaft 14, a hole in the front-rear direction extending through the entire shaft 14 is formed. The front part of the hole is a chuck hole 106 into which a bit can be mounted. A chuck 108 is provided outside the chuck hole 106 (at the tip of the shaft 14). In addition, an output adjustment mechanism 94 is disposed at the center of the hole (behind the chuck hole 106) so as to close the hole.
A sealed space is formed by the shaft 14, the front oil case 80, the rear oil case 81, the screws 82 and 82, the output adjustment mechanism 94, and various seal rings, and oil is sealed in the sealed space. .
The sealing of the oil into the sealed space is performed in a state of being evacuated through the holes of the screws 82 and 82, and the screws 82 and 82 are inserted after the oil sealing.
The oil in the sealed space can flow into the rear side of the ring 83 through the gaps 84a and 84a of the plate 84. The ring 83 can contract according to the pressure that flows into the rear side and receives from the adjacent oil. The ring 83 contracts mainly when the gas 83a is compressed, and contracts when the heat of the oil becomes relatively high and the pressure increases.

Further, a cam 85 is disposed at the rear portion of the hole inside the shaft 14 (behind the output adjustment mechanism 94).
The cam 85 has a flat shape (expands back and forth and up and down in FIGS. 3 and 4), and is provided so as to be able to rotate left and right together with the shaft 14.
Around the cam 85 (up and down in FIGS. 3 and 4), metal (iron) balls 86 and 86 are arranged. Each ball 86 can contact the cam 85. The shaft 14 is provided with a radial hole for receiving each ball 86. The hole communicates with a hole in the front-rear direction of the shaft 14.
A blade 88 is disposed outside each ball 86 (upper or lower in FIGS. 3 and 4). Each blade 88 can simultaneously contact the ball 86 and the inner wall of the rear oil case 81 (side wall portion 81a). When the raised portions 96, 96 of the side wall 81a are located on the left and right, the cam 85 becomes horizontal by rotation, and when the balls 86, 86 are located on the left and right of the cam 85, the blades 88, 88 are left or right. It hits the ridges 96,96. At this time, the radial oil passage holes 110 and 110 (FIG. 5) opened so as to communicate with the rear part of the front-rear direction hole of the shaft 14 are closed by the cam 85 and the balls 86 and 86, and the rear part of the shaft 14 is closed. The inside (the periphery of the cam 85) is sealed, and the internal pressure of the sealed portion becomes higher than the internal pressure of oil in other portions. Due to the increase in the internal pressure of the sealed portion, the position of each blade 88 (position where the blade 85 is pushed outward by the cam 85 and the ball 86 and can come into contact with the raised portion 96) is held.
The internal pressure of the oil can be adjusted by the output adjustment mechanism 94. The output adjusting mechanism 94 moves back and forth, so that the amount of oil passing through the rear of the output adjusting mechanism 94 is adjusted, thereby adjusting the internal pressure of the oil. The output adjustment mechanism 94 is moved back and forth by being rotated by an operation tool inserted into the chuck hole 106.
The shaft 14 is connected to the planetary gear mechanism 12 via the oil unit 13 and is rotationally driven by the planetary gear mechanism 12.

An example of the operation of the oil pulse driver 1 will be described.
When the user grips the grip portion 6 and pulls the switch lever 8, power is supplied from the battery 28 to the motor 10 by switching in the switch body portion 8 a, and the coil is generated by the control circuit board 38 based on information from the sensor board 44 or the like. 48, 48... (Drive coil) are sequentially switched, and the rotor shaft 50 rotates.

The rotation of the rotor shaft 50 causes the fan 60 to rotate, and an air flow (wind) from the front intake ports 27, 27 and the intake ports 62, 62,... To the exhaust ports 61, 61,. The internal mechanism such as the oil unit 13 is cooled.
More specifically, the fan 60 rotates to push the surrounding air toward the exhaust ports 61, 61... To generate wind, and the air introduced from the intake ports 62, 62. 40 and between the rotor 42 and the like, or the outside and exit from the exhaust ports 61 and 61 (refer to the motor 10 in FIG. 1 and FIG. 5 or each of the intake ports 62 and the vicinity of the exhaust ports 61). The wind in the motor 10 and its surroundings mainly cools the stator core 45 first through the outer periphery of the stator core 45, and then cools the sensor substrate 44 through the entire surface of the sensor substrate 44. Subsequently, these are cooled through the inner periphery of the rotor core 51, the coils 48 and the stator core 45.
In addition, air introduced from each front intake port 27 (ventilation path W0) passes through each gap 25 (ventilation path W1) and each hole 22c, and between the inner surface of the unit case 22 and the outer surface of the oil unit 13 (ventilation path W2). (Refer to the alternate long and short dash line near the front vent 27 in FIGS. 1 and 5). This wind further passes into the motor housing 20 through the air passage W3 between the outer surface of the planetary gear mechanism 12 (internal gear 72) and the inner surface of the unit case 22 (or the inner surface of the motor housing 20a), and the lower internal gear. It passes through the ventilation openings 78a and 78a formed in the gear fixing ribs 78 and 78 (see the one-dot chain line in FIG. 4). And this wind merges with the air introduced from the inlets 62, 62.

Further, the rotational force of the rotor shaft 50 is transmitted to the planetary gears 74, 74,... Via the pinion 57, and is decelerated by the planetary gears 74, 74,. It is transmitted to the carrier 77 via the pins 76, 76. The carrier 77 rotates the rear oil case 81 (and the front oil case 80) of the oil unit 13 through the rear portion 81c of the rear oil case 81.
Each blade 88 of the oil unit 13 is normally held in contact with the raised portion 96 of the side wall 81 a of the rear oil case 81. In this state, the oil passage holes 110 and 110 are blocked by the balls 86 and 86 and the cam 85, a high-pressure oil sealed space is formed around the cam 85, and the blades 88 and 88 are raised by the high-pressure oil. The positions of the blades 88 and 88 are held by being pressed against the portions 96 and 96. Then, the rotation of the rear oil case 81 is transmitted to the shaft 14 via each blade 88, each ball 86, the cam 85 and oil, and the bit fixed by the chuck 108 is rotated, and screw tightening or the like is performed.
On the other hand, when the screw 14 is tightened and the rotation of the shaft 14 is delayed from the rotation of the oil case 81 after the load on the shaft 14 is increased, the impact torque is reduced as follows. 13 is intermittently generated and applied to the shaft 14. That is, the rear oil case 81 and the shaft 14 rotate relatively, each blade 88 is once separated from the raised portion 96, and the cam 85 and each ball 86 open each oil passage hole 110, and the oil around the cam 85 is The sealed space is opened, and the balls 86 and the blades 88 are drawn inward in the radial direction to allow the relative rotation of the rear oil case 81 until each blade 88 reaches the next raised portion 96. When each blade 88 comes into contact with the next raised portion 96, the oil sealed space around the cam 85 is again sealed and filled with relatively high pressure oil, and the cam 85 and each ball 86 are interposed. The blades 88 are held at positions projecting radially outward and hit the raised portions 96, the impact torque is transmitted to the shaft 14, and the same operation is repeated as appropriate.
The oil unit 13 can generate an impact torque. When the impact torque is applied to the shaft 14, the screw can be tightened through the bit.
Even if the oil becomes hot due to operation and its volume expands, the hollow ring 83 is pressed and contracted by the oil, so that the increase of the internal pressure due to the oil is suppressed, and the fluctuation of the internal pressure due to the fluctuation of the oil temperature. Is adjusted by the ring 83.

In the oil pulse driver 1 described above, the motor 10, the pinion 57 rotated by the motor 10, the planetary gears 74, 74... Meshing with the pinion 57, and the internal gear 72 meshing with the planetary gears 74, 74. The shaft 14 is rotationally driven by the planetary gears 74, 74... And disposed in front of the planetary gears 74, 74..., And the internal gear 72 includes an internal tooth portion 72 c and an internal tooth portion. An internal tooth holding part 72a for holding 72c is provided, an oil unit bearing 97 is arranged in front of the internal tooth part 72c, and the oil unit bearing 97 is held in front of the internal tooth holding part 72a. ing.
Therefore, by superimposing the internal gear 72 and the oil unit bearing 97 in the radial direction, the oil pulse driver 1 can be shortened in the front-rear direction by an amount corresponding to the installation space, and is compact and easy to handle. it can.
Further, the motor 10, the pinion 57 rotated by the motor 10, the planetary gears 74, 74, meshing with the pinion 57, the internal gear 72 meshing with the planetary gears 74, 74,. , Holding pins 76, 76,..., A carrier 77 holding the pins 76, 76,... And a shaft 14 that is rotationally driven by the carrier 77 and disposed in front of the planetary gears 74, 74,. The carrier 77 is arranged on the inner peripheral side of the internal gear 72.
Therefore, by placing the carrier 77 inside the internal gear 72, the carrier 77 can be installed substantially in the installation space of the internal gear 72. The oil pulse driver 1 is short in the front-rear direction, compact and easy to handle. Can be provided.
Furthermore, it has a motor 10, a pinion 57 rotated by the motor 10, planetary gears 74, 74... Meshing with the pinion 57, and an internal gear 72 meshing with the planetary gears 74, 74. The internal gear 72 has an internal tooth part 72c and an internal tooth holding part 72a for holding the internal tooth part 72c. The internal tooth holding part 72a is provided in front of the oil unit bearing 97 and the rotor shaft 50. The bearing 56 is held, and a closed space is formed by the oil unit bearing 97 and the bearing 56.
Therefore, in the internal gear 72, the closed space can be formed by the first bearing and the second bearing that are installed for rotation of other members, and these bearings can have a plurality of functions. The oil pulse driver 1 can be provided at a low cost with a reduced number of parts and a less wasteful configuration.

In addition, the motor 10, a planetary gear mechanism 12 driven by the motor 10, a shaft 14 connected to the planetary gear mechanism 12 and driven to rotate by the planetary gear mechanism 12, and a unit case 22 that houses the planetary gear mechanism 12. Since the unit case 22 is made of resin, it is possible to provide the oil pulse driver 1 in which the unit case 22 can be easily formed and assembled.
Further, since the cover 24 is provided on the outer periphery of the unit case 22, the unit case 22 can be protected to improve durability, and the outer surface of the motor housing 10 and the outer surface of the cover 24 are flush with each other. Handleability can be improved.
Furthermore, a motor housing 20 for housing the motor 10 is provided, unit case mounting ribs 20c and 20c, stepped portions 20d and ribs 20e (fitting portions) are provided in the motor housing 20, and unit case ribs 22a and 22a are provided in the unit case 22. Since the (fitted part) is provided and the fitting part and the fitted part are fitted, the unit case 22 can be attached to the motor housing 20 with high strength and rigidity.
Furthermore, since the damper 26 is held on the cover 24, the unit case 22 can be protected from impact and the durability can be improved, and the outer surface of the cover 24 and the outer surface of the damper 26 are designed to be flush with each other. And handling properties can be improved.
Further, since the shaft 14 is connected to the oil unit 13 that can generate an impact torque, it is possible to provide the oil pulse driver 1 having the above-described effects.
In addition, the unit case 22 is prevented from being pulled out forward and prevented from rotating left and right by the front retaining portions (unit case mounting ribs 20c, 20c, stepped portion 20i) of the motor housing 20. The internal gear 72 is prevented from being pulled backward by the internal gear fixing ribs 78, 78... Of the motor housing 20, so that the unit case 22 and the internal gear 72 are placed in the motor housing 20. In an efficient configuration that can be firmly fixed, and prevents the unit case 22 from coming out in the direction away from each other, such as preventing the unit case 22 from coming out forward and stopping the internal gear 72 from coming out backward. These can be fixed.
In addition, since the cover 24 is provided with a hole 24d for fixing the damper 26 adjacent to the engaging portion 24c for stopping the rotation of the cover 24, the functions of both the rotation prevention of the cover 24 and the attachment of the damper 26 are achieved. It can be realized in a compact configuration.

Furthermore, the motor 10, the motor housing 20 that houses the motor 10, the oil unit 13 that is driven by the motor 10, the unit case 22 that houses the oil unit 13 and is connected to the motor housing 20, and the unit case 22 And the cover 24 that is held by the motor housing 20, the cover 24 for protecting the oil unit 13 is strong against the motor housing 20 to which the unit case 22 of the oil unit 13 is connected. In addition, it is possible to provide a compact oil pulse driver 1 that can be connected in a compact manner and in which an internal mechanism such as the oil unit 13 is sufficiently protected.
The motor housing 20 has a right motor housing 20b and a left motor housing 20a, and the cover 24 is sandwiched between the right motor housing 20b and the left motor housing 20a, so that the cover 24 can be easily assembled with high strength. Can do.
Further, the cover 24 is held by the motor housing 20 by being sandwiched between the right motor housing 20b and the left motor housing 20a while the cover 24 is held on the outer periphery of the unit case 22. Therefore, the unit case 22 and the cover 24 are compact. Thus, it can be combined with the motor housing 20 in a high strength state.
Further, the connecting portion (unit case mounting rib 20c, stepped portion 20d, rib 20e, unit case rib 22a) between the unit case 22 and the motor housing 20 is more than the light holding upper housing 20f of the motor housing 20 holding the cover 24. Since it arrange | positions back, the cover 24 which protects the unit case 22 can be arrange | positioned compactly, hold | maintaining the unit case 22 firmly.
Furthermore, the peripheral surface of the unit case 22 is connected to the inner surface of the motor housing 20 (the upper surface of the light holding upper housing 20f and the upper side of the unit case holding ribs 20g, 20g). Therefore, the unit case 22 can be firmly assembled to the motor housing 20, and the holding structure of the unit case 22 can be made compact.
In addition, since at least a part of the cover 24 is disposed inside the motor housing 20 and at least a part of the unit case 22 is disposed inside the cover 24, the motor housing 20, the unit case 22, The cover 24 can be combined in a compact manner.
Further, since the ventilation path W1 is provided between the cover 24 and the unit case 22, the cooling path and the dust discharge ventilation path W1 can be easily and compactly formed by projecting the shape of the cover from the outer surface of the unit case 22. Can be formed.
Furthermore, since the ventilation path W0 is provided between the cover 24 and the motor housing 20, the ventilation path W0 for cooling and dust discharge can be formed compactly and easily by combining these.
In addition, since the cover 24 is held between the light 32 and the unit case 22, the cover 24 can be efficiently held in a compact configuration.

In addition, this invention is not limited to the said form, For example, the following changes can be given suitably.
The internal tooth holding part and the internal tooth part may be separated from each other, and the internal tooth holding member and the internal tooth member may be used. In this case, the internal gear is formed by attaching the internal gear member to the internal gear holding member.
Then, the motor 10, the pinion 57 rotated by the motor 10, the planetary gears 74, 74, meshed with the pinion 57, the internal gear meshed with the planetary gears 74, 74,. A shaft 14 that is rotationally driven by and arranged in front of the planetary gears 74, 74..., And the internal gear has an internal gear member and an internal gear for holding the internal gear member If it has a tooth holding member, an oil unit bearing 97 is arranged in front of the internal tooth member, and the oil unit bearing 97 is held at the front portion of the internal tooth holding member, it is short in the front-rear direction and is compact and easy to handle. An oil pulse driver can be provided.
The motor 10, the pinion 57 rotated by the motor 10, planetary gears 74, 74... Meshing with the pinion 57, and the internal gear meshing with the planetary gears 74, 74. The internal gear includes an internal gear member and an internal gear holding member for holding the internal gear member, and the internal gear holding member includes an oil unit bearing 97 and a bearing 56 in front of the rotor shaft 50. If a closed space is formed by the oil unit bearing 97 and the bearing 56, the bearing can have a plurality of functions, the number of parts can be reduced, and a low-cost and compact oil pulse driver can be provided.

  Alternatively, instead of combining the motor housing 20 and the unit case 22 by fitting, the unit case 22 may be screwed to the motor housing 20. In this screwing, for example, the motor housing 20 is provided with (a plurality of) screw hole portions, and the unit case 22 is provided with (a plurality of) screw holes at portions corresponding to the screw hole portions. Screws can be passed through the part and (respectively) screw holes. Even in this case, the motor housing 20 and the unit case 22 can be firmly combined.

As the battery, any lithium ion battery of 18 to 36V such as 18V (maximum 20V), 18V, 25.2V, 28V, 36V, etc. may be used, and a lithium ion battery having a voltage of less than 14.4V or more than 36V may be used. You may use and another kind of battery may be used.
A gear group having a different number of teeth may be used for the reduction gear portion instead of the planetary gear mechanism or together with the planetary gear mechanism.
The unit case may be fixed with four screws to the left motor housing and the right motor housing.
Increase or decrease the number of housing sections, such as the grip part of the motor housing as a separate body, increase or decrease the number of various gears installed, change the switch type of the switch lever, and do not exhibit a phosphorescent property of the damper It is possible to appropriately change the number and arrangement of various members, the material, the size, the type, the integration and separation of members, and the like.
The oil unit is omitted, a hammer case is used instead of the unit case, an impact mechanism including a hammer and anvil is provided in the hammer case as an impact mechanism that replaces the oil unit, and an impact driver (rotating impact tool) is provided. The oil unit is omitted and a gear case is used instead of the unit case. Further, for example, a reduction mechanism such as a two-stage planetary gear mechanism is arranged, and the output shaft of the reduction mechanism is projected forward from the gear case. Electric rotating tools and impact tools other than oil pulse drivers, such as rechargeable driver drills or vibration driver drills, by fixing the tip tool holding part that holds the tip tool (bit) to the front part of the output shaft It is also possible to do. Further, instead of the battery or with the battery, a power cord may be provided and connected to the power source so that power can be supplied from the power source.

  1 ・ ・ Oil pulse driver (electric rotary tool, impact tool), 10 ・ ・ Motor, 13 ・ ・ Oil unit (impact mechanism), 14 ・ ・ Shaft, 20 ・ ・ Motor housing (housing), 20a ・ ・ Left motor Housing (left housing), 20b ... Right motor housing (right housing), 20c ... Unit case mounting rib (fitting part, connection part, front retaining part), 20d ... Step part (fitting part, connection) Part), 20e .. rib (fitting part, connection part), 20f .. holding part, 20g .. unit case holding rib (holding part), 20i .. step part (front retaining part), 22 .. unit Case (case), 22a ··· Unit case rib (fitting part), 24 · · Cover, 24c · · Engagement portion (prevention of locking and rotation), 24d · · Hole (for damper fixing), 26 · · · damper, 2 .. Light, 56 .. Bearing (second bearing), 57 .. Pinion, 72 .. Internal gear, 72 a .. Internal tooth part, 72 c .. Internal tooth holding part, 74 .. Planetary gear, 76 .. Pins 77 .. Carrier 78 .. Internal gear fixing rib (prevention), 97 .. Oil unit bearing (first bearing), W 0, W 1.

Claims (9)

A motor,
A reduction gear unit driven by the motor;
An output unit connected to the reduction gear unit and driven to rotate by the reduction gear unit;
A case for accommodating the reduction gear portion;
An electric rotary tool having
An electric rotary tool characterized in that the case is made of resin. The electric rotary tool according to claim 1, wherein a cover is provided on an outer periphery of the case. Providing a housing for housing the motor;
A fitting portion is provided in the housing,
A fitting portion is provided in the case,
The electric rotary tool according to claim 1 or 2, wherein the fitting portion and the fitted portion are fitted. The electric rotary tool according to claim 2, wherein a damper is held on the cover. The electric rotating tool according to claim 4, wherein the output unit is connected to an oil unit capable of generating impact torque. Providing a housing for housing the motor;
The electric rotary tool according to any one of claims 1 to 5, wherein the case is screwed to the housing. Providing a housing for housing the motor;
The electric rotary tool according to any one of claims 1 to 6, wherein an impact mechanism portion is disposed inside the case. The case is prevented from slipping forward and left and right by the front retaining portion of the housing, and the reduction gear portion is moved rearward by the rear retaining portion of the housing. The electric rotary tool according to any one of claims 1 to 7, characterized in that it is prevented from coming off. The electric rotating tool according to any one of claims 4 to 8, wherein a hole for fixing the damper is provided in the cover adjacent to an engaging portion that stops rotation of the cover. .

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