JP2014113664A - Electric power tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric power tool which enables an entire substrate for a brushless motor etc. to be fixed to a stator of a brushless motor achieving sufficient strength.SOLUTION: An impact driver 1 includes: a brushless motor 10 having a stator 32 and a rotor 30 which may rotate relative to the stator 32; and an output part (a spindle 14, a hammer 16, and an anvil 18) driven by the brushless motor 10. A circuit board 60 is fixed to the stator 32 and a wiring connection part 91 is provided on the circuit board 60. An outer shape of the circuit board 60 is formed so as to be smaller than an outer shape of the stator 32.

Description

  The present invention relates to an electric tool using a brushless motor as a drive source.

As shown in Patent Document 1 below, an impact driver equipped with a DC brushless motor is known.
In this impact driver, a sensor board on which a magnetic sensor for detecting the position of the magnetic pole of the rotor in the DC brushless motor is mounted is fixed to the rear end of the stator of the DC brushless motor.
A power line (lead wire) for connection with the coil is connected to the sensor substrate. The power line is connected to a flexible tongue-like portion protruding from the disk-shaped sensor substrate body at the lower portion of the sensor substrate.

Japanese Patent No. 498345

In the conventional impact driver as described above, the sensor substrate from which the tongue-shaped portion protrudes is fixed in a state where the sensor substrate body is in contact with the rear end portion of the stator of the DC brushless motor. The part protrudes, and the outer shape of the sensor substrate is larger than the outer shape of the stator. Therefore, the sensor board (especially the tongue-shaped part) may not be firmly fixed, and the sensor board may not be able to secure sufficient strength against unexpected sudden movement of the lead wire. The part has the possibility of breaking.
Therefore, the main object of the present invention is to provide an electric tool that can sufficiently fix the strength of the entire substrate for a brushless motor or the like to the stator of the brushless motor.

In order to achieve the above object, the invention according to claim 1 is an electric tool including a stator, a brushless motor having a rotor rotatable with respect to the stator, and an output unit driven by the brushless motor. The circuit board is fixed to the stator, the wiring board is provided on the circuit board, and the outer shape of the circuit board is smaller than the outer shape of the stator.
In order to achieve the above object, a second aspect of the present invention includes a motor housing, a handle housing extending downward from the motor housing, a gear case disposed in front of the motor housing, and an interior of the motor housing. A brushless motor having a stator and a rotor having a rotation shaft that is rotatable with respect to the stator and extends in the front-rear direction; a gear that is disposed inside the gear case and transmits the rotation of the rotor; An electric power tool having an output shaft to which rotation of the gear is transmitted and projecting from the gear case, wherein a circuit board is fixed to the stator, a wiring connection portion is provided on the circuit board, and The length of the circuit board in the vertical direction is smaller than the length.
According to a third aspect of the present invention, in the above invention, the circuit board includes six switching elements.
According to a fourth aspect of the present invention, in the above invention, the stator includes a stator core, an insulating member, and a coil, and the coil is wound around the stator core via the insulating member. The circuit board is fixed to the insulating member with a screw.
According to a fifth aspect of the present invention, in the above invention, the circuit board is disposed behind the insulating member, a lead wire is held in the wiring connection portion, and the lead wire is the circuit board. It extends from the rear surface.
According to a sixth aspect of the present invention, in the above invention, the lead wire passes through an outer peripheral portion (including a lower portion) of the circuit board.
According to a seventh aspect of the present invention, in the above invention, the circuit board is disposed behind the insulating member, a lead wire is held in the wiring connection portion, and the lead wire is the circuit board. It is characterized by extending from the front surface.
According to an eighth aspect of the present invention, in the above invention, a gap is provided between the circuit board and the insulating member, and the lead wire is passed through the gap.
The invention according to claim 9 is the above invention, wherein the lead wire is a power supply lead wire for supplying power to the coil, a rotation detection signal lead wire for outputting from the circuit board, and the circuit board. A switching element drive signal lead wire for inputting to the circuit board, and the power supply lead wire, the rotation detection signal lead wire, and the switching element drive signal lead wire are fixed to a lower portion of the circuit board. It is characterized by this.

According to the first aspect of the present invention, since the outer shape of the circuit board is smaller than the outer shape of the stator, the entire circuit board for a brushless motor or the like has sufficient strength against the stator of the brushless motor. There is an effect that it can be fixed.
According to the second aspect of the present invention, the circuit board is fixed to the stator of the brushless motor, the wiring connection portion is provided on the circuit board, and the vertical length of the circuit board is larger than the vertical length of the stator. Since the structure is small, the entire circuit board for a brushless motor or the like can be sufficiently fixed with respect to the stator of the brushless motor.
Furthermore, according to the invention described in claim 3, in the above invention, since the circuit board has six switching elements, in addition to the above effect, a large number of switching elements can be protected by firmly fixing the circuit board. There is an effect that it is possible.
In addition, according to the invention of claim 4, in the above invention, the coil is wound around the stator core via the insulating member, and the circuit board is fixed to the insulating member with a screw. There is an effect that the circuit board and the like can be more firmly fixed.
According to the invention of claim 5, in the above invention, the circuit board is disposed behind the insulating member, the lead wire is held in the wiring connection portion, and the lead wire extends from the rear surface of the circuit board. In addition to the above effects, there is an effect that wiring without interference can be easily performed.
Further, according to the invention described in claim 6, in the above invention, the lead wire is passed through the outer peripheral portion (including the lower part) of the circuit board. The effect that it can arrange | position to is produced.
In addition, according to the invention described in claim 7, in the above invention, the circuit board is disposed behind the insulating member, the lead wire is held in the wiring connection portion, and the lead wire is extended from the front surface of the circuit board. In addition to the above effects, there is an effect that space can be saved on the rear side of the brushless motor and the circuit board.
According to the invention described in claim 8, in the above invention, since the gap is provided between the circuit board and the insulating member and the lead wire is passed through the gap, in addition to the above effect, the lead wire is not sandwiched. The effect that it can arrange | position appropriately is produced.
Furthermore, according to the invention described in claim 9, in the above invention, the power supply lead wire, the rotation detection signal lead wire, and the switching element drive signal lead wire are fixed to the lower part of the circuit board. There is an effect that the wiring can be made appropriate in the electric tool in which the control board is arranged.

It is a right view of the impact driver which concerns on the 1st form of this invention. It is a center longitudinal cross-sectional view in FIG. FIG. 2 is a rear view of the brushless motor in FIG. 1. It is a rear surface side perspective view of the brushless motor of FIG. It is a partial circuit diagram in the brushless motor of FIG. It is a center longitudinal cross-sectional view of the impact driver which concerns on the 2nd form of this invention. FIG. 7 is a rear view of the brushless motor in FIG. 6. It is a lower surface side perspective view of the brushless motor of FIG. It is a center longitudinal cross-sectional view of the impact driver which concerns on the 3rd form of this invention. FIG. 10 is a front view of the brushless motor in FIG. 9. It is a front side perspective view of the brushless motor of FIG. It is a center longitudinal cross-sectional view of the impact driver which concerns on the 4th form of this invention. It is a front view of the brushless motor in FIG. It is a lower surface side perspective view of the brushless motor of FIG.

  Hereinafter, embodiments of the present invention and modifications thereof will be described with reference to the drawings as appropriate.

[First form]
FIG. 1 is a right side view of an impact driver 1 which is an example of an electric tool (rotating impact tool) according to the first embodiment, and FIG. 2 is a longitudinal sectional view of the center of the impact driver 1 (screws 3, 3,... Brushless motor). FIG. 3 is a rear view of the brushless motor 10, and FIG. 4 is a rear perspective view of the brushless motor 10.
The impact driver 1 has a housing 2 that forms an outline thereof. In FIG. 1, the right is the front. The housing 2 is formed so that it can be divided in half on the left and right sides, and the left and right portions are engaged with each other by a plurality of screws 3, 3.
The impact driver 1 includes a cylindrical main body portion 4 having a central axis in the front-rear direction, and a grip portion 6 (handle portion) 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 at the base end portion of the grip portion 6.
A forward / reverse reversing switch 9 for sequentially switching the rotation direction of the brushless motor 10 is provided behind the switch lever 8.

The main body 4 of the impact driver 1 includes, in order from the rear side, a brushless motor 10, a spindle 14 including a planetary gear mechanism 12 (excluding an internal gear 94 described later), a coiled spring 15 that is an elastic body, and a hammer 16. And the anvil 18 are accommodated coaxially.
The brushless motor 10 is a drive source of the impact driver 1, and its rotation is decelerated by the planetary gear mechanism 12 and then transmitted to the spindle 14. Then, the rotational force of the spindle 14 is converted into a rotational impact force by the hammer 16 or the like, and is transmitted to the anvil 18 while receiving a buffer of the spring 15 passed between the spindle 14 and the hammer 16 as appropriate. The anvil 18 is an output shaft that receives a rotational impact force and rotates around the axis.
The spindle 14, the hammer 16, and the anvil 18 constitute an output unit that is driven by the brushless motor 10.

The housing 2 in the main body 4 includes a motor housing 20 that houses the brushless motor 10, and a hammer case 22 that is disposed in front of the motor housing 20 and houses the hammer 16.
Inlet holes 34, 34,... Are opened on the left and right sides of the rear portion of the motor housing 20, respectively, and exhaust ports 35, 35 are opened in front (up and down) thereof.
The hammer case 22 has a cylindrical shape whose front part is reduced in diameter relative to the rear part, and is attached by a part of the rear part entering the front part of the motor housing 20.
A dish-like gear case 24 is attached to the inside of the motor housing 20 and the hammer case 22 so as to be sandwiched between them (while being held by the hammer case 22). The gear case 24 has a hole in the center and a shape in which an adjacent portion of the hole is recessed with respect to the outside thereof, the recessed portion is disposed so as to be recessed rearward, and the bottom surface of the recessed portion is It is provided in a posture along the vertical direction.
A cylindrical cover 36 having an outer shape continuous with the motor housing 20 is covered on the front side of the motor housing 20 outside the gear case 24, and a cylindrical rubber cap 37 is covered on the front side thereof. Yes. In FIG. 2, the cover 36 and the rubber cap 37 are omitted.
On the other hand, the housing 2 in the grip 6 is a handle housing 26. The handle housing 26 is provided integrally with the lower portion of the motor housing 20 and extends downward from the motor housing 20.
A battery mounting portion 21 is provided at the lower portion of the handle housing 26. A battery connection terminal 27 and a control board 28 are disposed in the battery attachment portion 21, and a battery 29 is attached to the battery attachment portion 21. Slits 23 are provided on both sides of the battery attachment portion 21. In FIG. 2, the battery 29 is omitted.
The battery 29 includes a slider 25 on the front surface. The slider 25 is slidable up and down and is urged upward. When the slider 25 is at the upper side, the slider 25 is locked to the battery mounting portion 21. When the slider 25 is shifted downward, the slider 25 is released from the locked state. It is a detachable member.
An attachment hole 38 (here, a screw hole) for attaching a hook or the like is formed in the upper center right front side of the battery attachment portion 21.
Further, a switch display unit 33 for displaying the state of various switches and the like is provided above the front side of the battery mounting unit 21. Here, the switch display unit 33 is configured by a liquid crystal display.

The brushless motor 10 includes a rotor 30 that is a rotor and a stator 32 that is a stator.
The rotor 30 includes a rotating shaft 40, a front bearing 42 that supports the front portion of the rotating shaft 40, a rear bearing 44 that supports the rear end portion of the rotating shaft 40, and the rotating shaft 40 at the center of the rotating shaft 40. And a magnet 46 provided integrally therewith. A fan 48 for discharging dust, heat and the like is provided integrally with the rotary shaft 40 on the rear side of the front bearing 42. A pinion 49 is fixed to the front end portion of the rotating shaft 40.
The front bearing 42 is held at the rear center of the gear case 24, and the rear bearing 44 is held at the inner center of the rear end of the motor housing 20.
The stator 32 is disposed in a cylindrical stator case 50 whose axial direction is the front-rear direction, a disk-shaped front insulating member 52 disposed on the front side of the stator case 50, and a rear side of the stator case 50 or in the stator case 50. The disc-shaped rear insulating member 54, the gear-shaped stator core 55 disposed in the stator case 50, and the tooth portions of the stator core 55 in the stator case 50 via the rear insulating member 54, respectively. A plurality (six in this case) of coils 56, 56,.
Further, the rear surface of the rear insulating member 54 is provided with a plurality of concave portions 58, 58,... Recessed forward with respect to the other rear surface portions so as to extend in the radial direction. Further, a plurality of small protrusions 59, 59,... Projecting rearward are provided on the peripheral edge of the rear surface of the rear insulating member 54 excluding the concave portions 58.

A disc-shaped circuit board 60 is installed on the rear side of the rear insulating member 54.
The diameter of the circuit board 60 is slightly smaller than the diameter of the stator 32 (the stator case 50 and the rear insulating member 54). Therefore, the outer shape of the circuit board 60 is formed smaller than the outer shape of the stator 32. Further, the vertical length of the circuit board 60 is formed smaller than the vertical length of the stator 32.
The circuit board 60 is disposed such that the rear surface of the rear insulating member 54 excluding the concave portions 58 and the corresponding portion of the substantially flat front surface of the circuit board 60 are in contact with each other. A gap 61 is formed between them.
The outside air introduced into the housing 2 from the intake hole 34 by the fan 48 can flow into the brushless motor 10 through the gaps 61.
The circuit board 60 has a plurality of small holes 62, 62,. The small holes 62, 62... Are arranged so as to correspond to the arrangement of the small protrusions 59, 59..., And the small protrusions 59 are arranged in the small holes 62, 62. One of 64.
Further, the circuit board 60 has a plurality of notches 66, 66 on the periphery (lower left and right), and screws 68 are screwed into these notches, so that the circuit board 60 can be It is fixed to the insulating member 54.

The circuit board 60 includes a plurality (six here) of switching elements 70, 70... And a plurality (three here) of rotation detection elements 72, 72.
The switching elements 70, 70,... Are arranged in a ring shape so as to be located at the respective vertices of the hexagon, and the rotation detecting elements 72, 72,... Are arranged at equal intervals on the circuit board 60. Has been.
.. Are formed on the rear surface of the rear insulating member 54 of the stator 32. The circuit board 60 and the coils 56 are connected to the coil connection portions 73, 73,. The parts 73 are electrically connected to each other.

FIG. 5 shows a drive circuit 74 of the impact driver 1 including the switching elements 70, 70... And the rotation detection elements 72, 72,.
The drive circuit 74 includes a power supply circuit section 76, a three-phase bridge circuit section 78 including switching elements 70, 70,..., And a control circuit section 80 that controls the switching elements 70, 70,.

The power supply circuit portion 76 is a portion that is mainly disposed on the control board 28 and that suppresses voltage fluctuations of power supplied from the battery 29 via the battery connection terminal 27. And a power supply smoothing capacitor 84 connected in parallel to the power supply leads 82 and 82.
A switch 86 having a switch lever 8 is interposed between the power supply leads 82 and 82. In each power lead 82, a power lead 82a is provided between the switch 86 and the circuit board 60, and a power lead 82b is provided between the switch 86 and the terminal 27 (see FIG. 2).

  The three-phase bridge circuit unit 78 is connected to the power supply leads 82 and 82 in parallel with the power supply smoothing capacitor 84 and has three output lines extending from between the pair of switching elements 70 and 70. Each output line is connected to a corresponding coil 56 in the stator 32 of the brushless motor 10. An example of each switching element 70 is a field effect transistor (FET).

The control circuit unit 80 is a portion mainly disposed on the control board 28, and is configured to rotate by rotation detection signal lead wires 88, 88,... So that signals transmitted from the rotation detection elements 72 can be received. It is connected to the detection elements 72, 72,. Each rotation detection element 72 detects the position of the magnetic pole of the rotor 30 and transmits it as a rotation detection signal. Each rotation detection signal lead wire 88 is output from the circuit board 60 to the control board 28. It is a lead wire for. The control circuit unit 80 grasps and integrates the rotation detection signals transmitted from the respective rotation detection elements 72 and indicating the positions of the magnetic poles of the rotor 30, thereby determining the rotation state (rotation angle from the reference position) of the rotor 30. It is possible to obtain.
Then, the control circuit unit 80 turns on / off the switching elements 70, 70,... In the three-phase bridge circuit unit 78 according to the acquired rotation state of the rotor 30 (according to the state of each received rotation detection signal). A driving signal to be controlled is output to each of the switching elements 70, 70,. These drive signals are supplied to the control circuit unit 80 by a plurality of switching element drive leads 90, 90... (Shown collectively as one white arrow in FIG. 5) passed between the control board 28 and the circuit board 60. To the switching elements 70, 70..., That is, each switching element drive lead wire 90 is a lead wire for inputting these drive signals to the circuit board 60. By switching according to these drive signals, it becomes possible to flow an electric current sequentially to each coil 56 of the stator 32, and the rotation of the rotor 30 is executed.

The power supply lead wires 82 and 82 (power supply lead wires 82a and 82a), the rotation detection signal lead wires 88 and 88, and the switching element drive lead wires 90 and 90 and so on are respectively disposed below the disk-shaped circuit board 60. The wiring connection portion 91 thus connected is connected to the circuit board 60 so as to extend from the rear surface of the circuit board 60.
Various elements and lead wires on the circuit board 60 are mounted in a state in which the amount of protrusion from the front surface (the rear surface of the circuit board 60) is suppressed by a reflow method or the like (surface mounting, SMT: Surface Mount Technology). .
In the reflow method, solder printing according to a predetermined pattern is applied to the circuit board 60 (or an adhesive is applied to a component mounting position by a dispenser), various elements and lead wires are placed by a chip mounter, and the reflow furnace is used. This is a method in which heat is applied to melt the solder and various elements and lead wires are fixed, and there is no need to open through holes for mounting elements on the circuit board 60. Eliminates the need for soldering on the opposite side through the legs.
Further, a flexible substrate 93 for PWM signals is passed between the switch 86 and the control board 28.

On the other hand, a spindle bearing 92 that receives the rear end portion 14 a of the spindle 14 is installed inside the hollow portion of the gear case 24.
The spindle 14 is provided with a hollow disk-like portion 14b at the rear portion and in front of the rear end portion 14a. The disk-shaped part 14b protrudes outward (up, down, left and right) with respect to the other part of the spindle 14, and has a longer diameter than the other part.
A part of the planetary gear mechanism 12 is disposed in the disk-like portion 14 b of the spindle 14.
The planetary gear mechanism 12 includes an internal gear 94 having internal teeth, a plurality of planetary gears 96, 96... Having external teeth meshing with the internal gear 94, and pins 98 that are axes of the planetary gears 96. Including.
The internal gear 94 is non-rotatably attached inside the portion where the front portion of the gear case 24 and the rear end edge of the hammer case 22 overlap.
Most of each planetary gear 44 and each pin 46 are disposed in the disc-like portion 14 b of the spindle 14.
A plurality of front pin holes (as many as the number of pins 46) corresponding to the front end portions of the pins 46 are provided on the front surface of the disk-shaped portion 14b of the spindle 14. A plurality of rear pin holes corresponding to the rear end portions of the pins 46 are provided on the rear surface of the disk-shaped portion 14b. Each pin 46 is provided in the disk-shaped portion 14b with the front end portion being put in the front pin hole and the rear end portion being put in the rear pin hole. Each pin 46 is immovably pressed toward the hammer 16 by a washer 100 interposed between the front side of the disk-shaped portion 14b and the rear end of the spring 15.
Each planetary gear 96 is provided around the pin 46 so as to be rotatable around the corresponding pin 46. Each planetary gear 96 is arranged such that a part of the outer teeth protrudes outward from the disk-like portion 14b.
A spindle hole 14c, which is a hole from the rear surface to the front, is provided inside the spindle 14 and before and after the disk-like portion 14b. The tip of the rotating shaft 30 of the brushless motor 10 enters the spindle hole 14c, and the pinion 49 at the tip of the rotating shaft 30 has teeth that mesh with all the planetary gears 96 in common.

The hammer 16 has a recess 16a that is recessed in a cylindrical shape from the rear surface to the front, and the front portion of the spring 15 is contained in the recess 16a. A plurality of small balls 101, 101... Are interposed between the bottom (front end) of the recess 16 a and the front end of the spring 15.
In addition, between the hammer 16 and the front part of the spindle 14, balls 102, 102 for guiding the hammer 16 mainly in the front-rear direction at the time of hitting are interposed.

The anvil 18 on the front side of the hammer 16 has extended portions 18a and 18a extending in the radial direction at the rear end.
An anvil bearing 104 is provided on the front side of the extending portions 18a, 18a to support the anvil 18 so as to be rotatable around the axis and not to be displaced in the axial direction. The anvil bearing 104 is attached to the inner wall of the front end portion of the hammer case 22. An oil seal 106 formed of a ring-shaped elastic body is provided on the front side of the anvil bearing 104.
Further, a rear hole 18b, which is a hole from the rear surface to the front, is formed in the center of the rear part of the anvil 18, and the front end of the spindle 14 is inserted into the rear hole 18b in a state where the rotational impact force can be transmitted. It has been.
On the other hand, a chuck portion 18c for receiving a bit (not shown) is provided at the front portion of the anvil 18.
Chuck balls 108 and 108 corresponding to the small concave portions of the bit are provided vertically at the center of the chuck portion 18c.
Further, the outside of the chuck portion 18c is covered with a cylindrical sleeve 110, and a gap is formed between the outer surface of the front portion of the chuck portion 18c and the inner surface of the front portion of the sleeve 110, and a washer 112 is formed in the gap. Is provided. The washer 112 is locked by a retaining ring 114 buried in the outer surface of the tip end portion of the chuck portion 18c in a state of being in contact with the lower portion of the front surface.
Note that an LED 116 for illumination and a lens cover 118 thereof are provided on the lower front side of the main body 4 (upper side of the switch lever 8).

An operation example of such an impact driver 1 will be described.
When the operator grips the grip portion 6 (handle housing 26) and pulls the switch lever 8, power is supplied from the battery 29 to the brushless motor 10 (drive circuit 74), and control by the control board 28 and the circuit board 60 is performed. And the rotor 30 rotates.
The rotational force of the rotor 30 is decelerated by the planetary gears 96, 96... Running while rotating in the internal gear 94, and then transmitted to the spindle 14 via the pins 98, 98.
The spindle 14 rotates the anvil 18 and guides the hammer 16 to swing back and forth (hit) when a torque exceeding a predetermined threshold is applied to the anvil 18. At the time of impact, the buffering action by the spring 15 acts on the hammer 16 (or the spindle 14).

The impact driver 1 described above has a stator 32, a brushless motor 10 having a rotor 30 rotatable relative to the stator 32, and an output unit (spindle 14, hammer 16 and anvil 18) driven by the brushless motor 10. The circuit board 60 is fixed to the stator 32, and the wiring connection portion 91 is provided on the circuit board 60 so that the outer shape of the circuit board 60 is smaller than the outer shape of the stator 32. Therefore, the circuit board 60 can be firmly fixed to the stator 32 with sufficient strength, and the wiring on the circuit board 60 and the wiring connection portion 91 can be protected.
The motor housing 20, the handle housing 26 extending downward from the motor housing 20, the gear case 24 disposed in front of the motor housing 26, the motor housing 26, the stator 32, and the stator 32 A brushless motor 10 having a rotor 30 having a rotary shaft 40 that is rotatable and extends in the front-rear direction, and a gear (an internal gear 94 and each planetary gear 96) disposed inside the gear case 24 and transmitting the rotation of the rotor 30. ) And the anvil 18 that is transmitted from the gear case and protrudes from the gear case 24, the circuit board 60 is fixed to the stator 32, and the wiring connection portion 91 is provided on the circuit board 60. The vertical length of the circuit board 60 is smaller than the vertical length of the stator 32. It was. Accordingly, the circuit board 60 can be sufficiently fixed to the stator 32, and the wiring on the circuit board 60 and the wiring connection portion 91 can be protected.

Further, since the circuit board 60 is provided with the six switching elements 70, 70,..., Any of the many switching elements 70 on the circuit board 60 can be protected.
Still further, the stator 32 has a stator core 55, a rear insulating member 54, and coils 56, 56,..., And the coils 56, 56,. The circuit board 60 is fixed to the rear insulating member 54 with screws 68 and 68. Therefore, the circuit board 60 and the like can be fixed more firmly.
The circuit board 60 is disposed behind the rear insulating member 54, and a lead wire is held in the wiring connection portion 91, and the lead wire extends from the rear surface of the circuit board 60. Therefore, the circuit board 60 can be arranged avoiding the front side of the brushless motor 10 to which the front end portion of the rotating shaft 40 is directed, and can be further wired behind the brushless motor 10, so that there is no interference with the brushless motor 10. Can be easily performed.
In addition, the lead wires (the power supply lead wires 82, the rotation detection signal lead wires 88, and the switching element drive lead wires 90) pass through the outer peripheral portion (downward) of the circuit board 60. Therefore, even if the circuit board 60 does not have a conventional tongue-like portion, the lead wires can be appropriately arranged with few obstacles.
Further, the circuit board 60 is disposed behind the rear insulating member 54, and lead wires (each power supply lead wire 82, each rotation detection signal lead wire 88, each switching element drive lead wire 90) are connected to the wiring connection portion 91. These lead wires extend from the rear surface of the circuit board 60. Therefore, the circuit board 60 can be brought into close contact with the rear insulating member 54 including the back side of the wiring connection portion 91, and the circuit board 60 can be fixed in a higher strength state.
Further, the lead wires include power supply leads 82 and 82 for supplying power to the coils 56, 56..., Rotation detection signal lead wires 88, 88. Switching element drive signal lead wires 90, 90,... For power input, power supply lead wires 82, 82, rotation detection signal lead wires 88, 88,. 90... Are fixed to the lower part of the circuit board 60. Therefore, various lead wires can be gathered under the circuit board 60, and wiring on the circuit board 60 with sufficient strength can be easily performed.
The circuit board 60 is not arranged between the fan 48 and the part other than the fan 48 of the brushless motor 10, and the circuit board 60 is arranged on the opposite side of the fan 48, so that the inside of the brushless motor 10 is effective. Heat can be released.
In addition, since the lead wire has a structure that is arranged on the inner side and the rear side of the outer periphery of the brushless motor 10, it is less susceptible to vibration than the structure that is arranged on the outer side of the outer periphery of the brushless motor 10 and rearward. It has a structure. For this reason, the situation which a disconnection etc. generate | occur | produce in a lead wire by vibration can be prevented.

[Second form]
6 is a diagram corresponding to FIG. 2 of the impact driver 201 according to the second embodiment, FIG. 7 is a diagram corresponding to FIG. 3 of the second embodiment, and FIG. 8 is a diagram corresponding to FIG.
The impact driver 201 of the second form is configured in the same manner as the first form except for the arrangement of the circuit board 260 or various lead wires. Hereinafter, members similar to those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

The circuit board 260 of the second form is the same as the circuit board 60 of the first form except for the wiring connection portion 291.
The wiring connection part 291 is provided in the lower part of the front surface of the circuit board 260. The switching elements 70, 70... And the rotation detecting elements 72, 72... Are arranged on the rear surface of the circuit board 260.
In the wiring connection portion 291, power supply lead wires 82, 82, rotation detection signal lead wires 88, 88... For output from the circuit board 260, and switching element drive signal lead wires 90 for input to the circuit board 260. 90... Are connected in a state in which the amount of protrusion from the surface of the circuit board 260 (the length in the front-rear direction necessary for appropriate wiring) is suppressed, as in the first embodiment.
In front of the wiring connecting portion 291, a recess 58 (a gap 61 between the rear insulating member 54 and the circuit board 260) below the rear insulating member 54 of the brushless motor 10 is disposed, and each power lead 82 and each rotation The detection signal lead wire 88 and each switching element drive signal lead wire 90 extend through the gap 61 in the direction of the control board 28 and the switch 86 (downward).
Note that the outside air can flow into the brushless motor 10 through each gap 61.

Also in the impact driver 201 of the second form, the circuit board 260 is fixed to the stator 32, the wiring connection portion 291 is provided on the circuit board 260, and the outer shape of the circuit board 60 is configured to be smaller than the outer shape of the stator 32. The circuit board 260 can be firmly fixed to the stator 32 with sufficient strength, and the wiring in the circuit board 260 and the wiring connection portion 291 can be protected.
In particular, the circuit board 260 is disposed behind the rear insulating member 54, and lead wires (each power supply lead wire 82, each rotation detection signal lead wire 88, each switching element drive lead wire 90 are connected to the wiring connection portion 291. Since these lead wires extend from the front surface of the circuit board 260, various lead wires can be appropriately arranged even when the space behind the brushless motor 10 is small. The length of the main body portion 4 in the front-rear direction can be shortened, and the impact driver 201 can be easily handled.
Further, since the gap 61 is provided between the circuit board 260 and the rear insulating member 54 and these lead wires are passed through the gap 61, the circuit board is provided with the wiring connection portion 291 provided on the front side of the circuit board 260. Even if 260 is attached to the rear side of the stator 32, the lead wires can be properly arranged without being sandwiched.
It should be noted that the outside air that has flowed from the air inlets 34 provided at the rear of the motor housing 20 can flow into the brushless motor 10 without being obstructed by the lead wires. Therefore, the cooling efficiency of the brushless motor 10 can be improved.

[Third embodiment]
9 is a view corresponding to FIG. 2 of the impact driver 301 according to the third embodiment, FIG. 10 is a view corresponding to FIG. 3 of the third embodiment, and FIG. 11 is a view corresponding to FIG.
The impact driver 301 of the third form is configured similarly to the first form except for the arrangement of the brushless motor 310, the circuit board 360, and various lead wires. However, in the motor housing 20, the intake ports 34, 34... (See FIG. 1) according to the first form are exhaust ports in the present embodiment (and the fourth form described later), and the exhaust ports 35, 35 (see FIG. 1) is an intake port in this embodiment (and a fourth embodiment described later). Hereinafter, members similar to those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

The brushless motor 310 of the third form is formed by replacing the stator 332 with a front-rear symmetrical one according to the stator 32 of the first form while maintaining the front and rear of the rotor 30 in the same manner as the first form. The fan 48 is disposed on the rear side of the stator 332 and on the front side of the rear bearing 44.
In particular, the front insulating member 352 at the front part of the stator 332 has a front-rear symmetrical shape of the rear insulating member 54 of the first form, and the front surface of the front insulating member 352 has recesses 358, 358. Is formed.
Further, the rear insulating member 354 at the rear portion of the stator 332 has a symmetrical shape with respect to the front insulating member 52 of the first embodiment.

On the other hand, the circuit board 360 of the third form is the same as the circuit board 60 of the first form except that the front and rear are reversed.
Each switching element 70 and each rotation detecting element 72 are mounted on the front side of the circuit board 360.
The wiring connection part 391 is provided in the lower part of the front surface of the circuit board 260.

The circuit board 360 is attached to the front surface of the front insulating member 352 at the front portion of the stator 332 with screws 68, 68, and the like.
Since the front insulating member 352 has recesses 358, 358,..., Gaps 361, 361,... Are opened between the front surface of the front insulating member 352 and the rear surface of the circuit board 360.
Outside air can flow into the brushless motor 10 via each gap 361.

Also in the impact driver 301 of the third form, the circuit board 360 is fixed to the stator 332, the wiring connection portion 391 is provided on the circuit board 360, and the outer shape of the circuit board 360 is configured to be smaller than the outer shape of the stator 332. The circuit board 360 can be firmly fixed to the stator 332 with sufficient strength, and the wiring in the circuit board 360 and the wiring connection portion 391 can be protected.
In particular, since the circuit board 360 is disposed in front of the stator 332, the wiring can be located near the center of the housing 2, and the space below and behind the brushless motor 310 can be omitted, and the impact driver 301 ( The rear part of the main body 4 can be made compact.

[Fourth form]
12 is a diagram corresponding to FIG. 2 of the impact driver 401 according to the fourth embodiment, FIG. 13 is a diagram corresponding to FIG. 3 of the fourth embodiment, and FIG. 14 is a diagram corresponding to FIG.
The impact driver 401 of the fourth form is configured in the same manner as the third form except for the arrangement of the circuit board 360 and various lead wires. Hereinafter, the same reference numerals are given to the same members as those in the third embodiment, and description thereof will be omitted as appropriate.

The circuit board 460 of the fourth form is the same as the circuit board 360 of the third form except for the wiring connection portion 491.
The wiring connection portion 491 is provided at the lower part of the rear surface of the circuit board 260. The switching elements 70, 70... And the rotation detecting elements 72, 72... Are arranged on the front surface of the circuit board 260.
A recess 358 (a gap 361 between the front insulation member 352 and the circuit board 460) below the front insulation member 352 of the brushless motor 310 is disposed in front of the wiring connection portion 491, and each power lead 82 and each rotation detection. The signal lead wire 88 and each switching element drive signal lead wire 90 pass through the gap 361 and extend in the direction (downward) of the control board 28 and the switch 86.
Note that the outside air can flow into the brushless motor 10 through the gaps 361.

Also in the impact driver 401 of the fourth form, the circuit board 460 is fixed to the stator 332, the wiring connection portion 491 is provided on the circuit board 460, and the outer shape of the circuit board 460 is configured to be smaller than the outer shape of the stator 332. The circuit board 460 can be firmly fixed to the stator 332 with sufficient strength, and the wiring in the circuit board 460 and the wiring connection portion 491 can be protected.
In particular, since the circuit board 460 is disposed in front of the stator 332, the wiring can be located near the center in the housing 2, and the space below and behind the brushless motor 310 can be omitted, and the impact driver 301 ( The rear part of the main body 4 can be made compact.
Further, a gap 361 is provided between the circuit board 460 and the front insulating member 352, and lead wires (each power supply lead wire 82, each rotation detection signal lead wire 88, each switching element drive lead wire 90) are passed through the gap 361. Therefore, even if the circuit board 460 is attached to the front side of the stator 32 after the wiring connection portion 491 is provided on the front side of the circuit board 460, the lead wires can be properly arranged without being sandwiched.
Further, in the arrangement of the circuit board 460 and the lead wires in the fourth form, it is not necessary to bend the lead lines as compared with the third form, so that the lead lines are more difficult to break.
In addition, the circuit board 60 is disposed above the switch 86. Therefore, the lead wires (power supply lead wires 86a and 86a) from the circuit board 60 to the switch 86 can be easily arranged and can be easily connected.

[Modification example of the first to fourth embodiments]
In addition, this invention is not limited to the said form, For example, the following changes can be given suitably.
The wiring connection portion is provided in a portion (for example, the left end edge, the right end edge, or the upper end edge) other than the lower end edge of the circuit board. One or two of the three types of lead wires are separated from the remaining types and connected at other portions of the circuit board. Alternatively, each type is connected to a different location. Wiring is performed on the outer periphery such as the upper side, the right side, and the left side other than the lower part including the side of the circuit board.
The length in the left-right direction of the circuit board is made larger than the length in the left-right direction of the stator while the length in the vertical direction of the circuit board is made smaller than the length in the vertical direction of the stator. Even in this case, since the circuit board does not protrude in the vertical direction, the circuit board can be firmly fixed to the stator.
The circuit board is fixed to the stator by locking with the claw and its locking portion. Omit holes, small notches and small protrusions in the stator and circuit board. Also, increase or decrease the number of screws, claws, small protrusions, etc.
The gap between the stator and the circuit board may be formed by providing a recess on the circuit board side, or by forming a recess on both sides, or by providing a protrusion on at least one of them. It may be formed.
Various lead wire arrangements can be changed in various ways, for example, two power supply lead wires are divided into left and right parts (one is placed on the right side and the other is placed on the left side, etc.) )be able to.
Further, in the second embodiment, various lead wires may be passed through the gaps disposed on the sides and above.
Increase or decrease the number of housing divisions, the number of elements / coils or planetary gears installed, the number and type of lead wires, or the number of magnet poles, change the switch lever switch type, etc. The number, arrangement, material, size, type, type, and the like of various members can be changed as appropriate, such as changing the type of element.
Further, the present invention is applied to other rotary impact tools other than impact drivers, other impact tools, or other electric tools.

  1, 201, 301, 401 ·· Impact driver (electric tool) 10, 310 · · Brushless motor, 14 · Spindle, 16 · Hammer, 18 · Anvil, 20 · · Motor housing, 22 · Hammer case , 24 ·· Gear case, 26 · · Handle housing, 30 · · Rotor, 32, 332 · · Stator, 40 · · Rotating shaft, 52, 352 · · Front insulation member (insulation member), 54, 354 · · · Rear insulation Member (insulating member), 56, coil, 60, 260, 360, 460, circuit board, 61, 361, gap, 68, screw, 70, switching element, 82, power lead wire (lead wire) ), 88 .. Rotation detection signal lead wire (lead wire), 90 .. Switching element drive lead wire (lead wire), 91, 291, 391, 491. Connection portion, 94 ... inner teeth gear, 96 ... planet gear.

Claims (9)

A brushless motor having a stator and a rotor rotatable with respect to the stator;
An output unit driven by the brushless motor;
An electric tool having
Fixing a circuit board to the stator;
A wiring connection is provided on the circuit board,
An electric tool characterized in that an outer shape of the circuit board is smaller than an outer shape of the stator. A motor housing;
A handle housing extending downward from the motor housing;
A gear case disposed in front of the motor housing;
A brushless motor disposed inside the motor housing and having a stator and a rotor having a rotation shaft that is rotatable relative to the stator and extends in the front-rear direction;
A gear disposed inside the gear case and transmitting the rotation of the rotor;
An output shaft that transmits the rotation of the gear and protrudes from the gear case;
An electric tool having
Fixing a circuit board to the stator;
A wiring connection is provided on the circuit board,
An electric tool characterized in that the vertical length of the circuit board is smaller than the vertical length of the stator. The electric power tool according to claim 1, wherein six switching elements are arranged on the circuit board. The stator has a stator core, an insulating member, and a coil,
A coil is wound around the stator core via the insulating member,
The power tool according to any one of claims 1 to 3, wherein the circuit board is fixed to the insulating member with a screw. The circuit board is disposed behind the insulating member,
A lead wire is held in the wiring connection portion,
The power tool according to any one of claims 1 to 4, wherein the lead wire extends from a rear surface of the circuit board. The power tool according to claim 5, wherein the lead wire passes through an outer peripheral portion (including a lower portion) of the circuit board. The circuit board is disposed behind the insulating member,
A lead wire is held in the wiring connection portion,
The power tool according to any one of claims 1 to 4, wherein the lead wire extends from a front surface of the circuit board. A gap is provided between the circuit board and the insulating member,
The power tool according to claim 7, wherein the lead wire is passed through the gap. The lead wire includes a power supply lead wire for supplying power to the coil, a rotation detection signal lead wire for output from the circuit board, a switching element drive signal lead wire for input to the circuit board, Have
9. The power supply lead wire, the rotation detection signal lead wire, and the switching element drive signal lead wire are fixed to a lower portion of the circuit board. Power tools.

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