阅读说明：本技术 带有振动机构的电动工具 (Electric tool with vibration mechanism ) 是由 荒木裕太 长坂英纪 杉本学 于 2019-12-31 设计创作，主要内容包括：本发明提供一种带有振动机构的电动工具,能够防止金属制的箱体的磨损而提高耐久性。振动电动钻(1)包含：金属制的第2齿轮箱(41)；主轴(26),其被轴支撑于第2齿轮箱(41)内；第1凸轮(83),其被收容于第2齿轮箱(41),被固定为能够与主轴(26)一体旋转；第2凸轮(84),其被收容于第2齿轮箱(41),被设置为能够独立于主轴(26)进行旋转,并且被设置为能够与第1凸轮(83)接触；振动切换杆(95),其被设置为能够相对于第2齿轮箱(41)而在对第2凸轮(84)进行旋转限制的前进位置和解除该旋转限制的后退位置之间移动；以及承接部件(89),其夹在第2齿轮箱(41)和振动切换杆(95)之间。(The invention provides an electric tool with a vibration mechanism, which can prevent the abrasion of a metal box body and improve the durability. The vibrating electric drill (1) comprises: a 2 nd gear case (41) made of metal; a main shaft (26) supported by the shaft in the 2 nd gear case (41); a 1 st cam (83) housed in the 2 nd gear case (41) and fixed so as to be rotatable integrally with the main shaft (26); a 2 nd cam (84) housed in the 2 nd gear case (41), provided to be rotatable independently of the main shaft (26), and provided to be contactable with the 1 st cam (83); a vibration switching lever (95) that is provided so as to be movable relative to the 2 nd gear case (41) between a forward position at which the rotation of the 2 nd cam (84) is restricted and a backward position at which the restriction of rotation is released; and a receiving member (89) that is sandwiched between the 2 nd gear case (41) and the vibration switching lever (95).)

1. A power tool with a vibration mechanism, comprising:

a metal case;

a main shaft supported by the case;

a 1 st cam, at least a part of which is accommodated in the case and fixed to be rotatable integrally with the main shaft;

a 2 nd cam, at least a part of which is housed in the case, provided to be rotatable independently of the main shaft, and provided to be contactable with the 1 st cam;

a switching member provided movably with respect to the housing between a 1 st position where the 2 nd cam is rotationally restricted and a 2 nd position where the rotational restriction is released; and

a receiving member sandwiched between the case and the switching member.

2. The power tool with a vibration mechanism according to claim 1,

the housing is formed with a slit for movably accommodating the switching member, and the receiving member is fitted in the slit and movably holds the switching member.

3. The electric power tool with a vibration mechanism according to claim 1 or 2,

the switching member is provided in plurality, and the receiving members provided in the switching members are integrally connected to each other.

4. The electric power tool with a vibration mechanism according to any one of claims 1 to 3,

the receiving member is made of resin.

5. A power tool with a vibration mechanism, comprising:

a metal case;

a main shaft supported by the case;

a 1 st cam, at least a part of which is accommodated in the case and fixed to be rotatable integrally with the main shaft;

a 2 nd cam, at least a part of which is housed in the case, provided to be rotatable independently of the main shaft, and provided to be contactable with the 1 st cam;

a switching member provided to be movable relative to the housing between a 1 st position where the 2 nd cam is rotationally restricted and a 2 nd position where the rotational restriction is released; and

a resin sandwiched between the case and the switching member.

6. The power tool with a vibration mechanism according to claim 5,

the resin is fixed to the case side to guide the movement of the switching member.

Technical Field

The present invention relates to an electric power tool with a vibration mechanism, such as a vibration electric drill, which has a vibration mechanism and can selectively use a vibration mode.

Background

In an electric drill, for example, a vibration motor can transmit rotation of a motor housed in a housing to a spindle serving as an output shaft via a speed reduction mechanism, while a vibration mechanism capable of applying vibration in an axial direction along the spindle is disposed between the speed reduction mechanism and the spindle, and a vibration mode in which vibration is applied to the spindle and a drill mode in which vibration is not applied can be selected by a switching operation from outside the housing.

As disclosed in patent document 1, the main shaft is supported by a cylindrical portion provided in a metallic gear case (housing) held by a housing. In this case, the vibration mechanism is disposed in the cylindrical portion, and the vibration mode is switched by sliding the vibration switching member in the cylindrical portion.

Patent document

Patent document 1: japanese patent No. 3872897

Disclosure of Invention

In such an electric power tool, if the electric power tool is used in the vibration mode, the vibration switching member slightly vibrates in the cylindrical portion, and therefore, the cylindrical portion holding the vibration switching member may be worn.

Accordingly, an object of the present invention is to provide an electric power tool with a vibration mechanism capable of preventing abrasion of a metal case and improving durability.

In order to achieve the above object, the invention according to claim 1 is characterized by including: a metal case; a main shaft supported by the case; a 1 st cam, at least a part of which is accommodated in the case and fixed to be rotatable integrally with the main shaft; a 2 nd cam, at least a part of which is housed in the case, provided to be rotatable independently of the main shaft, and provided to be contactable with the 1 st cam; a switching member provided movably with respect to the housing between a 1 st position where the 2 nd cam is rotationally restricted and a 2 nd position where the rotational restriction is released; and a receiving member sandwiched between the case and the switching member.

The invention described in claim 2 is characterized in that, in addition to the configuration of claim 1, a slit for movably accommodating the switching member is formed in the case, and the receiving member is fitted in the slit to movably hold the switching member.

The invention described in claim 3 is characterized in that, in addition to the configuration of claim 1 or 2, a plurality of switching members are provided, and the receiving members provided in the respective switching members are integrally connected to each other.

The invention described in claim 4 is characterized in that, in any one of the configurations of claims 1 to 3, the receiving member is made of resin.

In order to achieve the above object, the invention according to claim 5 includes: a metal case; a main shaft supported by the case; a 1 st cam, at least a part of which is accommodated in the case and fixed to be rotatable integrally with the main shaft; a 2 nd cam, at least a part of which is housed in the case, provided to be rotatable independently of the main shaft, and provided to be contactable with the 1 st cam; a switching member provided movably with respect to the housing between a 1 st position where the 2 nd cam is rotationally restricted and a 2 nd position where the rotational restriction is released; and a resin sandwiched between the case and the switching member.

The invention described in claim 6 is characterized in that, in addition to the configuration of claim 5, the resin is fixed to the case side to guide the movement of the switching member.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the present invention, wear of the metal case can be prevented to improve durability.

Drawings

Fig. 1 is a side view of a vibrating electric drill.

Fig. 2 is a central longitudinal sectional view of the vibrating electric drill.

Fig. 3 is an enlarged view of the main body portion of fig. 2.

Fig. 4 is a perspective view of the gear assembly.

Fig. 5(a) is a side view of the gear assembly, (B) is a front view, and (C) is a half sectional view seen from above.

Fig. 6 is an exploded perspective view of the gear assembly.

Fig. 7 is a perspective view of the gasket, where (a) is a perspective view seen from the front, and (B) is a perspective view seen from the rear.

Fig. 8 is an explanatory view of the gasket, (a) is a front view, (B) is a plan view, (C) is a rear view, and (D) is a side view.

Fig. 9 is a central longitudinal section of the gear assembly, (a) is a central longitudinal section in the vibration mode, and (B) is a central longitudinal section in the drilling mode.

FIG. 10(A) is a sectional view taken along line A-A of FIG. 9, (B) is a sectional view taken along line B-B, and (C) is a sectional view taken along line C-C.

Description of the reference numerals

1 … vibrating electric drill, 2 … main body, 3 … handle, 4 … drill chuck, 5 … battery pack, 6 … main body shell, 9 … brushless motor, 18 … rotating shaft, 25 … gear assembly, 26 … main shaft, 40 … 1 st gear box, 41 … nd gear box, 42 … mode switching ring, 43 … clutch ring, 44 … large diameter portion, 45 … small diameter portion, 55 … speed reducing mechanism, 66 … vibrating mechanism, 67 … clutch mechanism, 83 … st 1 cam, 84 … nd 2 cam, 85 … engaging projection, 86 … liner, 89 … receiving member, 90 cam ring 90 … slit, 91 … guiding groove, 95 … vibrating switching rod, 96 … outer projection, 97 … inner projection, 99 …, 101 … notch.

Detailed Description

Embodiments of the present invention will be described below with reference to the drawings.

Fig. 1 is a side view of an oscillating electric drill showing an example of an electric power tool with an oscillating mechanism, and fig. 2 is a central longitudinal sectional view.

The vibration electric drill 1 is T-shaped when viewed from the side, and is formed by projecting a grip 3 from the lower side of a main body 2 extending in the front-rear direction, a drill chuck 4 capable of holding a drill by a tip is provided at the front end of the main body 2, and a battery pack 5 serving as a power source is attached to the lower end of the grip 3. The case is formed by attaching a cover-like rear cover 7 to the rear of a main body case 6, which is provided continuously with the handle 3 and the cylindrical rear half of the main body 2, from the rear by screws, not shown, and the main body case 6 is formed by attaching left and right split cases 6a and 6b by left and right screws 8 and 8 ….

As shown in fig. 3, an inner rotor type brushless motor 9 including a stator 10 and a rotor 11 penetrating the stator 10 is housed in a rear portion of the main body 2. The stator 10 is formed by winding a plurality of coils 14, 14 … around a stator core 12 made of laminated steel plates with front and rear insulators 13, 13 interposed therebetween, and is held coaxially with the cylindrical portion of the main body 2 in the front-rear direction by a rib provided in the main body case 6. A terminal fitting 15 welded to each phase coil 14 to form a three-phase connection is provided on the front insulator 13, the terminal fitting 15 protrudes below the stator 10, and a terminal unit 16 connected to a lead wire provided in a controller 33 described later is fixed to the terminal fitting 15 by screws and electrically connected to the controller 33. A sensor circuit board 17 is mounted on the front insulator 13, and a rotation detection element for detecting the magnetic field of the permanent magnet 20 provided on the rotor 11 is mounted on the sensor circuit board 17.

The rotor 11 is configured by fitting a permanent magnet 20 into a rotor core 19 having a rotating shaft 18 at its axial center, the rear end of the rotating shaft 18 is supported by a bearing 21 provided in the rear cover 7, and a fan 22 is fixed to the front of the rotating shaft. Exhaust ports 23, 23 … are formed on the outer periphery of the rear cover 7, and intake ports 24, 24 are formed on the outer side of the stator 10 on the left and right sides of the main body 2 (fig. 1).

A gear assembly 25 having a spindle 26 protruding forward from the main body housing 6 is attached to the front of the brushless motor 9, and the rotation of the rotary shaft 18 can be reduced and transmitted to the spindle 26. The drill chuck 4 is mounted to the front end of the spindle 26. A switch 27 for projecting a trigger 28 forward is housed below the gear assembly 25 on the upper portion of the handle 3. A forward/reverse switching button 29 of the brushless motor 9 is provided above the switch 27, and a lamp 30 having an LED for irradiating the front of the drill chuck 4 is housed in front of the switch.

On the other hand, a battery mounting portion 31 for slidably mounting the battery pack 5 from the front is formed at the lower end of the handle 3, a terminal block 32 electrically connected to the battery pack 5 is provided at the battery mounting portion 31, and a controller 33 is housed above the battery mounting portion, and the controller 33 has a control circuit board 34 on which a microcomputer, switching elements, and the like for controlling the brushless motor 9 are mounted.

As shown in fig. 4 to 6, the gear assembly 25 includes a 1 st gear case 40 having a cylindrical shape, a 2 nd gear case 41 having a cylindrical shape and attached to a front side of the 1 st gear case 40, a mode switching ring 42 and a clutch ring 43 attached to a front side of the 2 nd gear case 41. The 1 st gear case 40 is made of resin, the 2 nd gear case 41 is made of aluminum, the 2 nd gear case 41 has a two-stage cylindrical shape including a rear large diameter portion 44, a front small diameter portion 45, and a circular plate portion 46 connecting the rear large diameter portion and the front small diameter portion 45, and the 1 st gear case 40 is coupled to the large diameter portion 44 from the rear by screws 47 and 47 ….

The gear unit 25 is fixed to the main body case 6 by screwing 4 screw fixing portions 48 and 48 … provided on the outer periphery of the 2 nd gear case 41 to 4 screw bosses 49 and 49 … provided on the outer periphery of the main body case 6 from the front by screws 50 and 50 … (fig. 1). In this state, the front end of the rotary shaft 18 penetrates a bracket plate 51 that closes the rear end of the 1 st gear case 40, and is supported via a bearing 52. A pinion 53 is provided at the tip of the rotary shaft 18.

A reduction mechanism 55 is housed inside the gear unit 25, and the reduction mechanism 55 is configured by arranging carriers 57A to 57C supporting a plurality of planetary gears 58A to 58C revolving inside internal gears 56A to 56C in three stages in the axial direction, and the pinion gear 53 of the rotary shaft 18 is meshed with the planetary gear 58A of the first stage. The first-stage ring gear 56A, which meshes with the first-stage planetary gears 58A, is positioned on the carrier plate 51 via a spacer 59.

In addition, the internal gear 56B of the second stage can rotate and can move back and forth in the axial direction. The internal gear 56B may mesh with a coupling ring 60 held in the large diameter portion 44 in the advanced position.

On the other hand, in the rear half of the internal gear 56B, a speed switching ring 61 that can move forward and backward while being restricted from rotating in the 1 st gear case 40 is externally attached, and is integrally coupled in the front-rear direction by coupling pins 62, 62. A coupling piece 63 projecting upward from the speed switching ring 61 is coupled to a speed switching lever 64 provided slidably in the front-rear direction on the upper surface of the main body case 6 via front and rear coil springs 65, 65.

When the speed switching lever 64 is slid backward, the speed switching ring 61 is retreated via the connecting piece 63, and the internal gear 56B integrated therewith meshes with the outer periphery of the carrier 57A of the first stage while maintaining the meshing with the planetary gear 58B of the second stage. Therefore, the high-speed mode is performed in which the second-stage deceleration is canceled. Conversely, if the speed switching lever 64 is slid forward, the ring gear 56B moves forward together with the speed switching ring 61 by separating from the carrier 57A, and is engaged with the coupling ring 60 while maintaining the engagement with the second-stage planetary gear 58B, thereby being restricted from rotating. Therefore, the low speed mode in which the second stage deceleration acts is obtained.

Further, the gear assembly 25 is provided with: a vibration mechanism 66 that imparts vibration in the axial direction to the main shaft 26; and a clutch mechanism 67 that blocks torque transmission to the main shaft 26 under a predetermined load applied to the main shaft 26. That is, by the switching operation by the mode switching ring 42, the following modes can be selected, respectively: in the vibration drilling mode, the main shaft 26 vibrates axially along with rotation; in the drill mode, the main shaft 26 is rotated only; and a clutch mode (a driver mode) in which torque transmission to the main shaft 26 is blocked under a predetermined load. Next, each mechanism will be explained.

First, the main shaft 26 is axially supported by the front and rear bearings 68, 69 in the small diameter portion 45 of the 2 nd gear case 41, and the rear end thereof is spline-engaged with the lock cam 70 integral with the carrier 57C of the third stage in the rotational direction, and can move forward and backward in the axial direction. The lock cam 70 is rotatably provided in a cylindrical lock ring 71 located outside the lock ring and restricted from rotating in the small diameter portion 45, and rotation is transmitted from the carriage 57C by engagement between a pair of engaging portions 72 and claws 73 and 73 … provided to protrude from the front surface of the carriage 57C of the third stage. When the drill chuck 4 is rotated for attaching and detaching the drill in a state where the brushless motor 9 is stopped, the wedge pins 74 and 74 provided between the claws 73 are engaged between the chamfered portion of the lock cam 70 and the locking ring 71, thereby locking the rotation of the spindle 26.

In the vibration mechanism 66, the main shaft 26 is normally urged to an advanced position where a stopper ring 77 externally mounted at a rear position of the bearing 68 abuts against the bearing 68 by a coil spring 76 externally mounted between a flange 75 formed near the front thereof and the bearing 68 at the front side. A disk-shaped stopper plate 79 is fixed to the front surface of the small diameter portion 45 by 4 screws 78 and 78 …, and the bearing 68 is positioned between a stopper 80 fitted to the stopper plate 79 and a stopper ring 77. The stopper plate 79 abuts against the front surface of the clutch ring 43, and the mode switching ring 42 and the clutch ring 43 are prevented from coming off. A plurality of recesses 81, 81 … are formed on the outer periphery of the stopper plate 79, and a plate spring 82 elastically locked with the recesses 81 is fixed to the front end inner surface of the clutch ring 43.

Further, between the bearings 68 and 69 on the main shaft 26, an annular 1 st cam 83 and an annular 2 nd cam 84 are coaxially fitted from the front side. The 1 st cam 83 has a 1 st cam surface 83a formed of a plurality of radial teeth on the rear surface, and is fixed to the main shaft 26 at the rear of the stopper ring 77. The 2 nd cam 84 has a 2 nd cam surface 84a formed of a plurality of radial teeth on the front surface, is inserted into the main shaft 26 with a clearance fit, and has 6 engaging projections 85, 85 … projecting rearward at equal intervals in the circumferential direction on the outer periphery of the rear surface.

An annular packing 86 is provided in the small diameter portion 45 outside the 1 st cam 83. As shown in fig. 10(C), the spacer 86 abuts against the front bearing 68 in a state where rotation is stopped by engaging the protrusions 87, 87 provided on the outer periphery with the axial grooves 88, 88 provided on the inner periphery of the small diameter portion 45 from the front end.

The gasket 86 is made of resin, and a pair of receiving members 89, 89 for slidably holding vibration switching levers 95, 95 described later are integrally formed on the outer periphery of the gasket at a phase different from the phase of the convex strip 87 by 90 °, as shown in fig. 7 and 8. The receiving members 89, 89 are fitted into slits 90, 90 formed in the front end of the small diameter portion 45 in a state where the packing 86 is accommodated in the small diameter portion 45, and are accommodated in the small diameter portion 45, and close the front surface on the same plane flush with the front end of the small diameter portion 45, and have a cross-shaped guide groove 91 having a rear surface and a radial inner and outer opening on the inner surface.

Further, between the 2 nd cam 84 and the rear bearing 69, front and rear annular spacers 92, 92 holding a plurality of steel balls 93, 93 … therebetween are held in the small diameter portion 45, and the front annular spacer 92 abuts against the rear surface of the 2 nd cam 84 inside the engaging projection 85. The 2 nd cam 84 is restricted from moving forward by coming into contact with the spacer 86, and in this state, is separated from the 1 st cam 83 urged together with the main shaft 26 to the moving forward position.

On the other hand, in the receiving members 89, 89 of the spacer 86, a pair of vibration switching levers 95, 95 as switching members are respectively housed so as to be slidable in the front-rear direction. As shown in fig. 10(B) and (C), the vibration switching lever 95 is a rod-like body having a cross-shaped cross section and fitted into the guide groove 91 of the receiving member 89, and has an outer protrusion 96 protruding radially outward from the guide groove 91 on the outer side of the front end, as shown in fig. 9, and an inner protrusion 97 protruding radially inward from the guide groove 91 on the inner side of the rear end. The inboard projection 97 is located rearward of the 2 nd cam 84. Double coil springs 98, 98 having different outer diameters are held on the rear end inner surfaces of the slits 90, respectively, and bias the vibration switching lever 95 forward.

Therefore, the mounting of the pad 86 and the vibration switching levers 95 and 95 is performed as follows: in a state where the coil springs 98 and 98 are provided on the rear end inner surfaces of the slits 90 of the small diameter portion 45, the spacers 86 having the vibration switching levers 95 and 95 inserted into the receiving members 89 are fitted from the front side with the ridges 87 and the recessed grooves 88 and the receiving members 89 aligned in phase with the slits 90, respectively. This enables the mounting of the receiving member 89 and the vibration switching lever 95 simultaneously with the spacer 86.

A cam ring 99 housed inside the clutch ring 43 is coaxially connected to the front of the mode switching ring 42 via 3 connecting portions 100 and 100 … in the front-rear direction arranged along the circumferential direction, and an outer protrusion 96 of the vibration switching lever 95 abuts on the rear surface of the cam ring 99. A pair of trapezoidal notches 101, 101 (fig. 6) are formed in the rear surface of the cam ring 99, and at the rotational position of the mode switching ring 42 where the notch 101 is located forward of the outer protrusion 96, as shown in fig. 9(a), the vibration switching lever 95 is at the advanced position where the outer protrusion 96 fits in the notch 101, and the inner protrusion 97 is located between the engaging protrusions 85, 85 of the 2 nd cam 84. Therefore, the rotation of the 2 nd cam 84 is restricted.

A retaining ring 105 is fitted to the rear surface of the mode switching ring 42 so as to be rotatable integrally, a restricting ring 106 is fitted to the inside of the retaining ring 105, and outer protrusions 107 and 107 … are formed on the outer circumferential side of the restricting ring 106 at predetermined intervals in the circumferential direction, and inner protrusions 108 and 108 … are formed on the inner circumferential side of the restricting ring 106. The restricting ring 106 is rotatable integrally with the retaining ring 105 and movable in the axial direction with respect to the retaining ring 105 by fitting the outer protrusion 107 into the inner groove 109 provided on the inner periphery of the retaining ring 105.

As shown in fig. 10(a), 6 sets of engaging pins 110, 110 … which can move forward and backward through sleeves 111, … are held at equal intervals in the circumferential direction on the disk portion 46 behind the restricting ring 106, and the rear end of each engaging pin 110 can be engaged with a cam projection 112, 112 provided to protrude on the front surface of the rotatably provided third-stage ring gear 56C in the circumferential direction. On the outer concentric circle of the engagement pin 110, a steel ball 114 biased forward by a coil spring 113 is provided at 3 of the disk portion 46 as shown in fig. 3 and 9, and is fitted into recessed portions 115 and 115 … provided on the rear surface of the retaining ring 105. The locking (click) action is generated by using the 3 rotational positions at which the steel balls 114 are fitted into the recessed portions 115 as the positions of the respective operation dies.

On the other hand, a recessed portion 116 is formed in the root portion of the small-diameter portion 45, and an axial withdrawal groove 117 that communicates with the recessed portion 116 and opens forward is formed in the outer peripheral surface of the small-diameter portion 45. The small diameter portion 45 is externally provided with a spring holder 118 having engaging projections 119 and 119 … engaged with the ejection groove 117 and being movable in the axial direction in a state where rotation is restricted, and a clutch spring 120 is externally provided between the rear side thereof and the restricting ring 106. The spring bracket 118 can change the axial length of the clutch spring 120 by screwing an external thread portion 121 formed on the outer periphery into an internal thread portion 122 provided on the inner periphery of the clutch ring 43 and screwing the clutch ring 43 in the axial direction by the rotational operation.

Next, each operation mode selected by the mode switching ring 42 will be described.

First, at the rotation position a of the mode switching ring 42 where the notches 101, 101 are located forward of the outer protrusions 96, 96 of the vibration switching levers 95, as shown in fig. 9(a) and 10(B), the vibration switching levers 95, 95 advance in the receiving members 89, and the inner protrusions 97, 97 are located between the engaging protrusions 85, 85 of the 2 nd cam 84 to restrict the rotation of the 2 nd cam 84. Therefore, when the 1 st cam 83 rotating together with the main shaft 26 retreats, the 1 st and 2 nd cams 84 engage with each other via the 1 st and 2 nd cam surfaces 83a and 84 a.

At this rotational position a, the inward projection 108 of the retainer ring 106 engages with the retracted portion 116 of the small diameter portion 45, whereby the advance of the retainer ring 106 is restricted. In this state, the advance of each engagement pin 110 abutting against the front surface of the internal gear 56C is restricted to maintain the engagement with the cam boss 112, and therefore, the vibration drill mode is set in which the rotation of the internal gear 56C is restricted.

At the rotation position B after the mode switching ring 42 is rotated rightward as viewed from the front in the vibration drill mode, the notches 101 and 101 start to move from the front of the outer protrusions 96 and 96 in accordance with the rightward rotation of the cam ring 99, and the outer protrusions 96 and 96 move away from the notches 101 and 101 to retract the vibration switching levers 95 and 95. Therefore, as shown in fig. 9(B), the inner protrusions 97 and 97 move rearward from between the engaging protrusions 85 and 85 of the 2 nd cam 84, and the rotation restriction of the 2 nd cam 84 is released.

In this rotational position B, the inner protrusion 108 of the limiter ring 106 is located behind the exit groove 117 of the small diameter portion 45, so the limiter ring 106 can move forward and backward. Therefore, the clutch mode is set in which the biasing force of the clutch spring 120 is transmitted to the inner gear 56C via the engagement pin 110 without generating vibration, and the rotation of the inner gear 56C is restricted. That is, if a load exceeding the biasing force of the clutch spring 120 is applied to the main shaft 26, the cam boss 112 pushes up the engagement pin 110 forward to idle the internal gear 56C, thereby blocking torque transmission. The set torque can be changed by rotating the clutch ring 43 to screw the spring holder 118 in the axial direction, thereby changing the axial length of the clutch spring 120. When the clutch ring 43 is rotationally operated, the plate spring 82 elastically engages with the concave portion 81 of the stopper plate 79, and a lock feeling is generated.

At the rotation position C after the mode switching ring 42 is rotated rightward as viewed from the front in the clutch mode, the vibration switching levers 95 and 95 are retracted, the state in which the rotation restriction of the 2 nd cam 84 is released is maintained, and the inner protrusion 108 of the restricting ring 106 is moved in the circumferential direction from the rear of the ejecting groove 117 and is engaged with the retracted portion 116 again, whereby the forward movement of the restricting ring 106 is restricted. Therefore, the engagement pin 110 abuts against the front surface of the internal gear 56C without generating vibration, and the drill mode in which the cam boss 112 is restricted from passing is achieved.

In the vibrating electric drill 1 configured as described above, if the trigger 28 is pressed to turn ON the switch 27, the microcomputer of the controller 33 obtains a rotation detection signal indicating the position of the permanent magnet 20 of the rotor 11, which is output from the rotation detection element of the sensor circuit board 17, to acquire the rotation state of the rotor 11, and controls ON/OFF of each switching element based ON the acquired rotation state to cause current to flow sequentially through each phase coil 14 of the stator 10 to rotate the rotor 11. Therefore, since the spindle 26 is rotated via the speed reduction mechanism 55 by rotating the rotary shaft 18, the drill held by the drill chuck 4 can be used in the selected operation mode.

At this time, if the vibration drill mode is selected by the mode switching ring 42, the vibration switching levers 95, 95 are in the forward position and the rotation of the 2 nd cam 84 is restricted as described above, and therefore the 1 st cam 83 rotating together with the spindle 26 pushed into the workpiece and retreated generates vibration in the forward and backward direction by the 1 st and 2 nd cam surfaces 83a, 84a interfering with the 2 nd cam 84.

If vibration is generated in this way, the vibration is also transmitted to the vibration switching levers 95, but since the vibration switching levers 95, 95 are held to the small diameter portion 45 via the receiving members 89, 89 made of resin, the receiving members 89, 89 become buffer portions, and the inner surfaces of the slits 90, 90 of the small diameter portion 45 are less likely to be worn.

On the other hand, if the clutch mode or the drill mode is selected by the mode switching ring 42, the vibration switching levers 95 and 95 are in the retreated position and the rotation restriction of the 2 nd cam 84 is released as described above, and therefore the 1 st cam 83 rotating together with the main shaft 26 pushed into the workpiece and retreated does not vibrate even if it abuts against the 2 nd cam 84.

As described above, the vibrating electric drill 1 according to the above aspect includes: a 2 nd gear case 41 (case) made of metal; a main shaft 26 supported by the shaft in the 2 nd gear case 41; a 1 st cam 83 housed in the 2 nd gear case 41 and fixed to be rotatable integrally with the main shaft 26; a 2 nd cam 84 housed in the 2 nd gear case 41, provided to be rotatable independently of the main shaft 26, and provided to be contactable with the 1 st cam 83; a vibration switching lever 95 (switching member) provided movably with respect to the 2 nd gear case 41 between a forward position (1 st position) where the rotation of the 2 nd cam 84 is restricted and a backward position (2 nd position) where the restriction of the rotation is released; and a receiving member 89 interposed between the 2 nd gear case 41 and the vibration switching lever 95, whereby direct influence on the 2 nd gear case 41 can be reduced even if the vibration switching lever 95 vibrates. Therefore, even if the 2 nd gear case 41 made of metal is used, the wear of the 2 nd gear case 41 can be prevented and the durability can be improved.

In particular, here, since the slit 90 for movably receiving the vibration switching lever 95 is formed in the small diameter portion 45 of the 2 nd gear case 41 and the receiving member 89 is fitted in the slit 90 and movably holds the vibration switching lever 95, the 2 nd gear case 41 can be compactly received even if the separate receiving member 89 is used. In addition, the replacement of the receiving member 89 can be easily performed.

Further, since the plurality of vibration switching levers 95, 95 are provided and the receiving members 89, 89 provided to the respective vibration switching levers 95 are integrally connected to each other, even if the plurality of receiving members 89, 89 are integrally manufactured, it is possible to easily attach the vibration switching levers to the small diameter portion 45.

Further, since the receiving member 89 is made of resin, it can be easily formed and high cushioning properties can be obtained.

In the invention relating to the receiving member, the number and shape of the receiving member are not limited to the above-described embodiments, and may be appropriately changed in accordance with the number and shape of the vibration switching lever. In the above-described embodiment, the receiving member is integrated with the gasket to facilitate the manufacture and the installation, but may be formed separately from the gasket to be installed separately, or may be simply connected to each other.

The receiving member is not limited to resin, and may be made of metal such as iron or a composite of metal and resin as long as cushioning properties can be obtained.

Further, the vibrating electric drill 1 according to the above aspect includes: a 2 nd gear case 41 (case) made of metal; a main shaft 26 supported by the shaft in the 2 nd gear case 41; a 1 st cam 83 housed in the 2 nd gear case 41 and fixed to be rotatable integrally with the main shaft 26; a 2 nd cam 84 housed in the 2 nd gear case 41, provided to be rotatable independently of the main shaft 26, and provided to be contactable with the 1 st cam 83; a vibration switching lever 95 (switching member) provided movably with respect to the 2 nd gear case 41 between a forward position (1 st position) where the rotation of the 2 nd cam 84 is restricted and a backward position (2 nd position) where the restriction of the rotation is released; and a receiving member 89 (resin) interposed between the 2 nd gear case 41 and the vibration switching lever 95, whereby direct influence on the 2 nd gear case 41 can be reduced even if the vibration switching lever 95 vibrates. Therefore, even if the 2 nd gear case 41 made of metal is used, the wear of the 2 nd gear case 41 can be prevented and the durability can be improved.

In particular, since the receiving member 89 is fixed to the 2 nd gear case 41 side and guides the movement of the vibration switching lever 95, it can guide the movement in an appropriate shape corresponding to the vibration switching lever 95.

In the invention relating to the resin between the case and the switching member, it is needless to say that the shape of the receiving member may be changed, and the receiving member may be formed not separately from the case, but in the above-described embodiment, the resin may be integrally formed on the inner surface of the slit of the small diameter portion, or conversely, the resin may be integrally formed on the outer surface of the vibration switching lever, or the resin may be integrally formed on each of the inner surface of the slit and the outer surface of the vibration switching lever.

The cams of the vibration mechanism are not limited to being entirely housed in the case, and may be partially housed in the case, which is common among the inventions.

The present invention is not limited to the vibration electric drill, and may be applied to other electric tools with a vibration mechanism, such as a vibration drill that can switch between a vibration mode and a drilling mode, as long as the electric tools have a vibration mechanism and can switch whether or not to operate. The motor may be a commutator motor or the like instead of a brushless motor, or may be an AC tool using an AC power source instead of a battery pack.