JP7459315B2 - portable cutting machine - Google Patents

Description

This invention relates to a portable cutting machine, and more specifically to a portable cutting machine that uses an electric motor as a drive source.

Conventionally, a portable cutting machine (for example, a portable circular saw using a circular saw blade as a cutting tool) that can cut a material by driving various cutting tools using an electric motor as a drive source is already known (Patent Document (See 1) .

JP 2007-125796 A

The present invention is a portable cutting machine, which is provided with a lock button configured such that when one end is pushed in, the other end is pushed out, and the surface of the tip of the finger is pressed into the lock button without force. An object of the present invention is to provide a portable cutting machine that can be easily brought into contact with the end of the cutting machine.

According to one feature of the present disclosure, there is provided a portable cutting machine using an electric motor as a drive source, in which the handle portion extends in the front-rear direction, and the first contact portion at the front portion of the base portion and the front portion of the handle portion The device can be turned upside down by contacting the mounting surface at three points: the second contact portion and the third contact portion. A third contact portion was provided on the upper portion of the motor housing. Specifically, the third abutting part was located at the top of the motor housing in the vertical direction, and was disposed above the horizontal virtual plane.

Therefore, the portable cutting machine can be held upside down by using the three points (first contact part, second contact part, and third contact part) as support points when turned upside down and in contact with the mounting surface (up and down). (Can be placed upside down). When the portable cutting machine can be inverted in this manner, the longitudinal direction of the handle portion of the inverted portable cutting machine is approximately perpendicular to the mounting surface (for example, approximately 80°). That is, in this inverted state, the inclination of the handle portion in the longitudinal direction with respect to the vertical direction can be made small (for example, about 10 degrees). Therefore, when resuming an interrupted cutting operation, the operator can easily grasp the handle of the portable cutting machine in an inverted state.

According to another feature of the present disclosure, the third contact portion is located forward of the drive shaft of the electric motor in the front-rear direction.

Therefore, when the portable cutter is inverted, the longitudinal inclination of the handle portion with respect to the vertical direction can be made smaller. Therefore, when resuming the interrupted cutting operation, the operator can more easily grip the handle portion of the portable cutting machine in the inverted state.

According to another feature of the present disclosure, the position of the third abutting portion in the left-right direction is on the side opposite to the blade from the side surface on the side opposite to the blade when viewed from the front.

Therefore, the portable cutting machine can be held upside down with good balance.

According to another feature of the present disclosure, the third contact portion is a protrusion projecting from the motor housing.

Therefore, compared to the case where the protrusion is formed as a separate body from the motor housing and the protrusion formed as a separate body is retrofitted to the motor housing, the protrusion has sufficient strength. Can be secured.

According to another feature of the present disclosure, the protrusion is approximately trapezoidal or approximately triangular.

Therefore, more sufficient strength can be ensured in the protrusion.

FIG. 1 is a perspective view of a portable circular saw according to an embodiment. FIG. 2 is a plan view of the portable circular saw of FIG. 1; FIG. 2 is a front view of the portable circular saw of FIG. 1; FIG. 2 is a right side view of the portable circular saw of FIG. 1; FIG. 2 is a rear view of the portable circular saw of FIG. 1 . FIG. 2 is a left side view of the portable circular saw of FIG. 1 . 5 is a sectional view taken along the line VII-VII in FIG. 4. FIG. 3 is a sectional view taken along line VIII-VIII in FIG. 2. FIG. FIG. 2 is a perspective view of the portable circular saw of FIG. 1 viewed from the front, showing a state before a sliding plate is attached. 10 is a perspective view of the portable circular saw of FIG. 9 seen from the right side, showing a state inverted on the ground. FIG. FIG. 11 is a rear perspective view of the portable circular saw of FIG. 10. 10 is an exploded perspective view of the base of FIG. 9. FIG. 3 is a sectional view taken along the line XIII-XIII in FIG. 2. FIG. 3 is a sectional view taken along the line XIV-XIV in FIG. 2. FIG. 16 is a partially enlarged view of FIG. 15. FIG. FIG. 7 is a diagram illustrating another embodiment of assembling the sub-base to the main base. 1 is a perspective view of a prior art portable cutting machine shown in an inverted position; FIG.

Hereinafter, embodiments for carrying out the present invention will be explained using FIGS. 1 to 15. In the following description, a "portable circular saw 1" will be explained as an example of a "portable cutting machine." In addition, in the following description, the terms "top, bottom, front, back, left, and right" refer to the top, bottom, front, back, left, and right directions shown in the above-mentioned figures. That is, the front direction indicates the cutting direction (progressing direction) of the portable circular saw 1.

First, the portable circular saw 1 and the sliding plate 70 attached to the sliding surface 2b (lower surface) of the base 2 of the portable circular saw 1 will be explained individually.

First, the portable circular saw 1 will be described with reference to Figures 1 to 9. This portable circular saw 1 is composed of a roughly rectangular plate-shaped base 2 having a sliding surface 2b that is pressed and slid against the top surface of the material to be cut (e.g., wood, etc.) when performing cutting work, and a circular saw body 3 on the base 2 that has a disk-shaped saw blade 5 that is rotated and driven by an electric motor (brushless motor) 4 as a drive source (see Figures 1 to 6).

The circular saw body 3 is composed of a motor housing 6 that houses the electric motor 4, a handle housing 7 (handle portion) that is fastened to the motor housing 6 and extends in the front-to-rear direction, and a gear housing 8 that is fastened to the handle housing 7. Both ends of the drive shaft 9 of the electric motor 4 housed in the motor housing 6 are supported by bearings 10 and 11 (see Figure 7). The bearing 10 on the right side of the drive shaft 9 is attached to the gear housing 8, which will be described later.

Further, the bearing 11 on the left side of the drive shaft 9 is assembled to the inner surface of the motor housing 6. These allow the drive shaft 9 of the electric motor 4 to rotate smoothly. Further, a cooling fan 12 is assembled to the drive shaft 9 of the electric motor 4. Thereby, when the electric motor 4 is driven, the rotation of the drive shaft 9 causes the cooling fan 12 to also rotate, so that the electric motor 4 can be cooled.

At the tip of the protruding side (left side) of this motor housing 6, an arcuate rib 6b is formed toward the protruding direction. As a result, when the battery pack 31 is removed, the portable circular saw 1 can be erected horizontally to the left by the tips 6c of the ribs 6b. Therefore, it is easy to replace the saw blade 5 of the portable circular saw 1. Note that a notch 6d is formed before and after the rib 6b. Therefore, when the portable circular saw 1 is placed in a horizontal position tilted to the left, the space surrounded by the ribs 6b is not blocked. Therefore, even if the electric motor 4 is erroneously driven when the device is placed sideways, the device can be prevented from sticking to the floor by sucking air through the air intake port 6a.

The handle housing 7 is formed into a substantially loop shape so that its upper side has a grip portion 7a extending in the front-rear direction so that it can be gripped by one hand of an operator (see FIG. 1). This grip portion 7a corresponds to a “handle portion” described in the claims. A trigger 41 that can be pulled and operated by an operator to operate (ON) a switch (not shown) housed in the handle housing 7 is assembled inside the loop of the grip portion 7a.

A lock-off button 26 is provided on the front side of the grip portion 7a to enable the retracting operation of the trigger 41. The lock-off button 26 is provided with operating portions 26a and 26b that protrude left and right from the handle housing 7. This lock-off button 26 is configured such that when one of the operating portions 26a (operating portion 26b) is pushed in, the other operating portion 26b (operating portion 26a) is pushed out. As a result, the lock-off state of the trigger 41 is released, and the retracting operation of the trigger 41 becomes effective. For example, the imaginary lines in FIGS. 3 and 5 show a state in which, of the left and right operating sections 26a and 26b, the right operating section 26b is pushed in and the left operating section 26a is pushed out.

The left and right operating sections 26a and 26b each have a cylindrical shape cut by an inclined plane, and are integrated by an intermediate portion therebetween. More specifically, the operation parts 26a and 26b are formed so as to form an inclined surface 26c in which the upper side is cut out from the lower side in the vertical direction. This makes it easier to bring the tip surface of the fingertip into contact with the operating portion 26a or the operating portion 26b without strain. By doing so, even when the lock-off button 26, which requires a horizontal movement operation in the left-right direction, is not operated strictly in the left-right direction, but is operated in the left-right direction while applying a slight force downward. , you can operate it without any discomfort.

Further, a controller 27 is housed on the lower side of the handle housing 7. This controller 27 is connected to the electric motor 4 described above, a switch, and a power supply section 30 (battery pack 31) described later through lead wires (not shown). Thereby, when the operator pulls in the trigger 41, the electric motor 4 can be driven. The controller 27 includes a control circuit that transmits a control signal based on the rotational position information of the rotor 4b detected by the sensor board 4c, and a control circuit that controls the current of the electric motor 4 based on the control signal received from this control circuit. It is equipped with a drive circuit that performs switching, and an auto-stop circuit that cuts off power supply to the electric motor 4 to prevent an over-discharge or over-current state depending on the detection result of the state of the battery pack 31, and the like.

Further, a power supply section 30 is provided on the rear side of the motor housing 6, and a battery pack 31 can be attached to and removed from the power supply section 30 by sliding (see FIG. 1). The direction in which the battery pack 31 is attached by this slide is from the left to the right, and the direction in which the battery pack 31 is removed by this slide is from the right to the left. Thereby, the battery pack 31 can be easily attached and detached.

This gear housing 8 is integrally provided on the left side of a fixed cover 8a that covers approximately the upper half of the saw blade 5. Both ends of the intermediate shaft 14 housed in the gear housing 8 are supported by bearings 15 and 16 (see FIG. 7). The bearings 15 and 16 are assembled to the inner surface of the gear housing 8. Thereby, the intermediate shaft 14 accommodated in the gear housing 8 can be smoothly rotated. Further, the intermediate shaft 14 is provided with a second gear 17 that can mesh with the first gear 13 formed on the drive shaft 9.

Further, both ends of a final shaft (output shaft) 19 housed in the gear housing 8 are supported by bearings 20 and 21. A bearing 20 on the tip side of the final shaft 19 is housed in the gear housing 8 via a bearing box 22 having a cylindrical shaft portion 23. Further, a bearing 21 on the proximal end side of this final shaft 19 is assembled to the inner surface of the gear housing 8. Thereby, the final shaft 19 accommodated in the gear housing 8 can be smoothly rotated.

A fourth gear 24 that can mesh with a third gear 18 formed on the outer peripheral surface of the intermediate shaft 14 is keyed to the final shaft 19. Note that the saw blade 5 described above is fastened via a bolt 25 so as to be orthogonal to the tip of the final shaft 19. Thereby, when the electric motor 4 is driven, the saw blade 5 can be rotated via the drive shaft 9, the intermediate shaft 14, and the final shaft 19.

Further, on the front side of the fixed cover 8a, an angular plate 35 having an arc-shaped guide groove 35b is assembled to the upper surface 2a of the base 2 with fixing screws 35c and 35d. To explain this structure in detail, female threads are provided in two places on the left and right at the lower end of the angular plate 35 in the vertical direction, and a through hole is provided in the corresponding position of the base, and a fixing screw 35c and a screw are inserted from below the base 2. It can be installed by inserting 35d. The through hole in the base of the fixing screw 35c on the right side has a small diameter, and the clearance with the threaded portion of the fixing screw 35c is very small. The through hole in the base of the left fixing screw 35d is about 1 mm larger in radius than the threaded portion of the fixing screw 35d. With these structures, the angular plate 35 can be rotated around the fixing screw 35c, and the parallelism with respect to the base 2 can be adjusted. A bracket 32, which is U-shaped in plan view, is connected to the angular plate 35 via a support shaft 35a so that it can be fixed at any position along the guide groove 35b (see FIGS. 2 and 3). The bracket 32 can be fixed at any position by tightening the lever 36. Further, the front end of the fixed cover 8a is attached to the bracket 32 so as to be swingable in the vertical direction by a support shaft 33 (see FIGS. 2 and 4).

On the other hand, a guide bolt 8c that protrudes leftward through a screw hole 8b is tightened on the rear side of the fixed cover 8a (see FIG. 8). Also, on the rear side of the fixed cover 8a, an angular plate 38 is provided upright on the upper surface 2a of the base 2 (see FIGS. 2 and 5). A bracket 37, which is U-shaped in plan view, is connected to the angular plate 38 via a support shaft 35a so that it can be fixed at any position along the guide groove 38a. The bracket 37 can be fixed at any position by tightening the thumbscrew 38b.

A depth guide 39 having a guide groove 39a that curves forward in an arc shape on the side of the fixed cover 8a is connected to the bracket 37 via a support shaft 37a. A guide bolt 8c with a ring member 8d inserted therein is inserted into the guide groove 39a of the depth guide 39 (see FIG. 8). A nut 8g having a lever 8f is tightened on the guide bolt 8c with a compression spring 8e inserted therein. The inner diameter of this compression spring 8e is set to be slightly larger than the outer diameter of the guide bolt 8c. Therefore, the inserted compression spring 8e can be prevented from shaking.

The free length of the compression spring 8e is set to be longer than the thickness of the depth guide 39. Therefore, when the lever 8f is operated to tighten the nut 8g, both ends of the compression spring 8e come into contact with the ring material 8d and the nut 8g. This makes it possible to deflect the abutting compression spring 8e. When the lever 8f is operated to tighten the nut 8g, the fixed cover 8a can be fixed at any position along the guide groove 39a of the depth guide 39 (see FIG. 5). Therefore, by changing the joining position (clamp position) of the fixed cover 8a along the depth guide 39, the circular saw body 3 can be swung around the support shaft 33, and the amount of protrusion of the saw blade 5 below the base 2 (the cutting depth of the saw blade 5) can be adjusted.

On the other hand, when the lever 8f is operated to loosen the nut 8g, the ring material 8d can be moved away from the nut 8g by the restoring force of the compression spring 8e (see FIG. 8). Therefore, a gap can be secured between the nut 8g and the depth guide 39 and between the depth guide 39 and the ring material 8d. Therefore, the frictional resistance generated between the nut 8g and the depth guide 39 and between the depth guide 39 and the ring material 8d can be reduced. As a result, the depth guide 39 can be smoothly moved up and down around the support shaft 37a. That is, the swingability of the circular saw main body 3 with respect to the base 2 can be improved.

In addition, by loosening the lever 36 and changing the fixed position of the bracket 32 with respect to the angular plate 35, the circular saw body 3 can be tilted to the right around the support shaft 35a from the perpendicular position where the saw blade 5 is perpendicular to the base 2. The lever saw blade 5 can be fixed to the base 2 at any inclination angle up to a maximum inclination position, for example, at an angle of about 45°. Note that a guide portion 40 is formed at the front end of the base 2, and the side edges are located on the extension of the saw blade 5 at the right angle (0°) position and the approximately 45° position of the saw blade 5. By aligning the side edge of the guide portion 40 with the ink line marked on the top surface of the guide part 40, cutting along the ink line is easily possible. Further, by rotating the reverse tilt switching lever 54 clockwise when viewed from above, the reverse tilt can be made up to −15°. The reverse inclination switching lever 54 is rotatable around a fixing screw 55, and a torsion spring 56 is provided on the fixing screw 55 to urge it counterclockwise. Therefore, when the circular saw main body 3 is returned from the reverse tilted state to the right angle, the reverse tilt switching lever 54 automatically rotates counterclockwise to return to the original state.

The movable cover 50 is attached to the underside of the fixed cover 8a (see FIG. 7). The movable cover 50 is attached to the bearing box 22 in such a manner that the insertion hole 71 is inserted into the shaft portion 23 of the bearing box 22 of the gear housing 8. This allows the inner circumferential surface 52 of the insertion hole 51 of the movable cover 50 to slide against the outer circumferential surface 23a of the shaft portion 23 of the bearing box 22, so that the movable cover 50 can be rotated relative to the bearing box 22 (gear housing 8). A tension spring 53 is hooked between a hook hole (not shown) of the fixed cover 8a of the gear housing 8 and a hook hole (not shown) of the movable cover 50. The tension spring 53 acts to close the movable cover 50.

Note that a square body 45 that projects upward is formed integrally with the left front side of the motor housing 6 (see FIGS. 1 and 9). This square body 45 corresponds to a "protrusion" described in the claims. This square body 45 is formed to have a substantially trapezoidal shape when viewed from the side (see FIG. 6). A recess 49a is provided on the left side surface 49 of the square body 45. The upper surface 46 of this square body 45 has a substantially rectangular shape (see FIG. 2), and among the four corners of this rectangle, the front left corner will be referred to as a first corner 46a for convenience of explanation.

As is clear from FIG. 6, the position of the first corner 46a of the square body 45 of the motor housing 6 in the front-rear direction is set to be further forward than the drive shaft 9 of the electric motor 4. Further, as is clear from FIG. 3, the position in the left-right direction of the first corner 46a of the square body 45 of the motor housing 6 is the side surface of the base 2 opposite to the saw blade 5 (the left side surface of the base 2) when viewed from the front. ) is set to be on the opposite side (left side) of the saw blade 5. The front surface 47 of the square body 45 is provided with a recess 47a. Further, there is a right front slope 48 on the right side and rear side adjacent to the front surface 47, and the right front slope 48 is also provided with a recess 48a that opens forward.

When the square body 45 is formed in this way, as shown in FIG. Using the first corner 46a) of the square body 45 as a support point, the portable circular saw 1 can be brought into contact with the ground E and turned upside down (it can be placed upside down). These "tip 36a of the lever 36", "front inclined part 7b of the handle housing 7", and "first corner 46a of the square body 45" are the "first contact part" described in the claims. , corresponds to a "second contact part" and a "third contact part".

By using these three points as support points to turn the portable circular saw 1 upside down, the longitudinal direction of the grip portion 7a of the handle housing 7 can be made approximately perpendicular (e.g., about 80°) to the ground surface E when the portable circular saw 1 is in the upside-down state (see FIG. 11). In other words, in this upside-down state, the inclination of the handle housing 7 (grip portion 7a) relative to the vertical direction can be made small (e.g., about 10°). Even if the inclination can be made small in this way, for example, the amount of overhang (protrusion) on the left side of the motor housing 6 itself does not become large. Therefore, the portable circular saw 1 can be prevented from becoming large in the left-right direction.

In addition, after the portable circular saw 1 has been temporarily placed due to an interruption in cutting work, when resuming the interrupted cutting work, the handle housing 7 of the portable circular saw 1 is placed upside down (placed upside down) behind the worker. It is possible to obtain the effect that the grip portion 7a is easy to grip. In addition, when the square body 45 is formed in this way, when the operator is cutting, the square body 45 can be placed at the finger rest area of the hand opposite to the hand that grips the grip portion 7a of the handle housing 7 ( Can be used as a sub grip part). Therefore, it is possible to obtain the effect that the cutting operation by the portable circular saw 1 can be stabilized.

The base 2 described above is composed of a main base 2x to which the circular saw body 3 is attached, and a sub-base 2y that can be detached from the right side of the main base 2x (see FIG. 12). Note that FIGS. 12 to 15 are specifically for explaining the main base 2x and the sub-base 2y. As is clear from FIG. 12, the angular plate 35 and the angular plate 38 of the main base 2x are provided with paired bosses 2x1. Each of the bosses 2x1 is formed with a recess 2x2 that opens to the right side (see FIG. 15).

As is clear from FIG. 15, the recess 2x2 is formed in the shape of a long hole whose longitudinal direction is the longitudinal direction. Specifically, the vertical length of the concave portion 2x2 is formed to be very slightly larger than the vertical length (diameter) of the convex portion 2y3. Further, the length of the concave portion 2x2 in the front-rear direction is sufficiently larger than the length (diameter) of the convex portion 2y3 in the front-rear direction.

In addition, at the rear (left side) of the recess 2x2 of the boss 2x1, a screw hole 2x3 into which a thumb screw 2z (described later) can be tightened is formed so as to be concentric with the recess 2x2 (see FIG. 14). The main base 2x is integrally formed by aluminum die casting. This allows the shape of the main base 2x to be finished with high precision. The sliding surface 2xx (lower surface) of the main base 2x is machined to create a flat surface.

The surface of the main base 2x is treated with nickel plating (surface treatment is performed after mechanical cutting of the sliding surface 2xx). The same integral molding by aluminum die casting, mechanical cutting, and surface treatment by nickel plating are also performed on the sub-base 2y, which will be described later. In other words, the sub-base 2y, which will be described later, is also integrally formed by aluminum die casting. The sliding surface 2yy (lower surface) of the sub-base 2y is also machine cut to make it flat.

On the other hand, a pair of bosses 2y1 are provided on the front left side and rear left side of the sub-base 2y so as to face the pair of bosses 2x1 of the main base 2x (see FIG. 12). An insertion hole 2y2 having a step 2y4 into which a thumbscrew 2z can be inserted is formed in the boss 2y1 so as to be concentric with the screw hole 2x3 of the recess 2x2 of the main base 2x. A cylindrical convex portion 2y3 is press-fitted into the insertion hole 2y2 so as to protrude from the exit side with an O-ring 2y5 inserted from the exit side (left side) to the step 2y4. The convex portion 2y3 is formed of a sleeve that can be inserted into the concave portion 2x2 of the main base 2x.

Further, a front position line 2y6 is marked on the right edge of this sub-base 2y at a position closer to the front (see FIG. 14). This front position line 2y6 indicates the position where the saw blade 5 starts cutting the material to be cut during the cutting operation. This allows the operator to recognize the position where the saw blade 5 starts cutting the material to be cut. On the contrary, a rear position line 2y7 is marked at a position near the rear of the right edge of this sub-base 2y. The rear position line 2y7 indicates the position where the saw blade 5 finishes cutting the material to be cut during the cutting operation. This allows the operator to recognize the position where the saw blade 5 finishes cutting the material to be cut. The same thing is also written on the left edge of the main base 2x.

Next, a procedure for assembling the sub-base 2y to the main base 2x will be explained. First, each convex portion 2y3 of the paired boss 2y1 of the sub-base 2y is inserted into each concave portion 2x2 of the paired boss 2x1 of the main base 2x. Next, the thumbscrews 2z are inserted into the O-rings 2y5 and the convex portions 2y3 from the insertion holes 2y2 of the paired bosses 2y1 of the sub-base 2y. The vertical length of the concave portion 2x2 is slightly larger than the vertical length (diameter) of the convex portion 2y3. Therefore, when this insertion work is performed, the sub base 2y can be vertically positioned with respect to the main base 2x at the same time as this insertion.

Therefore, when the sub-base 2y is assembled to the main base 2x, it is possible to easily ensure that the sliding surfaces 2xx and 2yy of both bases 2x and 2y are flush with each other. As a result, the ease of assembling the sub-base 2y to the main base 2x can be improved. At this time, the thumbscrew 2z is press-fitted into the O-ring 2y5. Therefore, the inserted knob screw 2z can be made difficult to come out from the O-ring 2y5. Therefore, the thumbscrew 2z can be prevented from falling out of the insertion hole 2y2 of the boss 2y1.

Next, the inserted thumbscrews 2z are tightened into the screw holes 2x3 of the pair of bosses 2x1 of the main base 2x. Thereby, the sub base 2y can be fixed to the main base 2x. That is, the sub-base 2y can be assembled to the main base 2x (see FIG. 13). Further, by performing the work in the reverse order to the above-described work procedure, the assembled sub-base 2y can be removed from the main base 2x.

When this sub-base 2y is assembled, it is possible to secure a pressing surface (sliding surface 2xx) against the material to be cut on the left side (inside) of the saw blade 5 during cutting work, while also ensuring a pressing surface (sliding surface 2xx) against the material to be cut on the right side (outside). A contact surface (sliding surface 2yy) can be secured. Therefore, the stability of the portable circular saw 1 in the left-right direction can be ensured during the cutting operation. On the other hand, if this sub-base 2y is removed, it is possible to cut at the edge of the material to be cut (for example, a floor surface close to a wall surface) during the cutting operation. Therefore, it is possible to provide so-called border convenience. Note that, as described above, since the shapes of the main base 2x and the sub-base 2y can be finished with high precision, the sliding surface 2yy of the sub-base 2y can be made flush with the sliding surface 2xx of the main base 2x. The portable circular saw 1 is configured as described above.

Both guide bodies 72 of the sliding plate 70 are each formed into a substantially inverted L shape from a vertical wall 73 and a horizontal wall 74. With this configuration, each vertical wall 73 of both guide bodies 72 has a shape that extends upward to a position facing the front edge 2c and rear edge 2d of the base 2. Moreover, each side wall 74 of both guide bodies 72 has a shape extending in a direction toward each other. Since both guide bodies 72 can sandwich the front edge 2c and rear edge 2d of the base 2, the sliding plate 70 can be inserted into the base 2. Note that a pair of insertion holes 73a are formed in the vertical wall 73 of the rear guide body 72 at positions corresponding to the respective hexagonal holes 63a of both fastening members 62 when the sliding plate 70 is inserted into the base 2. ing. The sliding plate 70 is configured in this way.

When the fastening member 62 is loosened, the head 63 of the loosened fastening member 62 presses against the inner wall surface 73c of the vertical wall 73 of the guide body 72 behind the sliding plate 70. That is, when the fastening member 62 is loosened, the head 63 of the loosened fastening member 62 presses against the edge of the insertion hole 73a of the vertical wall 73. At the same time, the front edge 2c of the base 2 presses against the inner wall surface 73c of the vertical wall 73 of the guide body 72 in front of the sliding plate 70. The amount of pressure can be adjusted by loosening or tightening the fastening member 62. The direction in which the fastening member 62 is loosened or tightened is the front-to-rear direction (planar direction) of the top surface 2a of the base 2.

Therefore, the base 2 and the guide body 72 behind the sliding plate 70 are tensioned via the fastening member 62. This restricts the relative movement between the base 2 and the sliding plate 70 in the front-to-rear direction, and as a result, the sliding plate 70 is attached to the sliding surface 2b of the base 2. In this way, the sliding plate 70 can be attached to the sliding surface 2b of the base 2 of the portable circular saw 1. Note that by performing the above-mentioned steps in the reverse order, the sliding plate 70 can be removed from the sliding surface 2b of the base 2 of the portable circular saw 1.

Finally, the operation of the portable circular saw 1 to which the sliding plate 70 is attached will be explained. When the trigger 41 is pulled in with the lower surface 71a (resin sheet 75) of the sliding plate 70 pressed against the upper surface of the material to be cut, the switch is activated (ON) and power is supplied from the battery pack 31 to the electric motor 4. is supplied. As a result, the electric motor 4 is driven, and the saw blade 5 is rotated via the drive shaft 9, intermediate shaft 14, and final shaft 19.

By rotating the saw blade 5 while pressing the lower surface 71a of the sliding plate 70 in this manner, the portable circular saw 1 is slid (slided) against the upper surface of the material to be cut. can be cut. At this time, the resin sheet 75 attached to the lower surface 71a of the sliding plate 70 can improve the slidability between the upper surface of the material to be cut and the lower surface 71a of the sliding plate 70. Therefore, the sliding operation of sliding the circular saw main body 3 against the upper surface of the material to be cut can be carried out smoothly. Therefore, the workability of cutting the material to be cut can be improved.

Note that as the material is cut in this manner, the material to be cut presses against the movable cover 50, so that the pressed movable cover 50 rotates against the biasing force of the tension spring 53. Eventually, when the cutting of the material to be cut is completed and the material to be cut is no longer pressed against the movable cover 50, the restoring force of the tension spring 53 returns the movable cover 50 to the closed state.

Moreover, as already explained, when the electric motor 4 is driven, the cooling fan 12 also rotates due to the rotation of the drive shaft 9. Then, outside air is taken in from the intake port 6a of the motor housing 6 (see FIG. 2). As shown in FIG. 2, this taken in outside air flows from the left side to the right side, thereby cooling the stator 4a and the rotor 4b. Further, the motor cooling air is blown out from the inner peripheral side of the baffle plate 28 through the gear housing 8 and into the fixed cover 8a. A portion of the motor cooling air is blown into the duct 29 through the inner peripheral side of the baffle plate 28.

As is clear from FIG. 2, the distal end side of the duct 29 faces toward the guide portion 40. Therefore, the motor cooling air blown into the duct 29 is blown out toward the guide portion 40 of the base 2. Therefore, the motor cooling air blown out from the duct 29 can blow away the cutting powder that accumulates on the guide part 40. Furthermore, the motor cooling air blown into the fixed cover 8a can blow away the cutting powder that accumulates at the cutting site C (see FIG. 4). By blowing off these cutting powders, the operator can clearly see the guide portion 40 and the slit line in addition to the cutting site C, thereby allowing the operator to perform accurate cutting work quickly.

The portable circular saw 1 according to the embodiment of the present invention is configured as described above. According to this configuration, the three points (the tip 36a of the lever 36 of the angular plate 35, the front inclined portion 7b of the handle housing 7, and the first corner 46a of the square body 45 of the motor housing 6) are used as support points to carry the device. The circular saw 1 can be placed upside down by contacting the ground E (it can be placed upside down). When the portable circular saw 1 can be inverted in this way, the longitudinal direction of the grip part 7a of the handle housing 7 of the inverted portable circular saw 1 is approximately perpendicular to the ground E (for example, about 80 degrees). There is. That is, in this inverted state, the longitudinal inclination of the grip portion 7a of the handle housing 7 with respect to the vertical direction can be made small (for example, about 10 degrees). Therefore, when restarting the interrupted cutting operation, the operator can easily grasp the grip portion 7a of the handle housing 7 of the portable circular saw 1 in the inverted state. In addition, when the square body 45 is formed in this way, when the operator is cutting, the square body 45 can be used as a finger rest part of the hand opposite to the hand that grips the grip portion 7a of the handle housing 7. Can be used. Therefore, the cutting operation by the portable circular saw 1 can be stabilized.

Further, according to this configuration, the position of the first corner 46a of the square body 45 of the motor housing 6 in the front-rear direction is set to be in front of the drive shaft 9 of the electric motor 4. Therefore, when the portable circular saw 1 is inverted, the longitudinal inclination of the grip portion 7a of the handle housing 7 with respect to the vertical direction can be made smaller. Therefore, when resuming the interrupted cutting operation, the operator can more easily grip the grip portion 7a of the handle housing 7 of the portable circular saw 1 in the inverted state.

Moreover, according to this configuration, the position of the first corner 46a of the square body 45 of the motor housing 6 in the left-right direction is lower than the side surface of the base 2 opposite to the saw blade 5 (the left side surface of the base 2) when viewed from the front. It is set to be on the opposite side (left side) of the saw blade 5. Therefore, the portable circular saw 1 can be inverted with good balance.

Further, according to this configuration, a square body 45 that projects upward is integrally formed on the left front side of the motor housing 6. Therefore, compared to the case where the square body 45 is formed as a separate body from the motor housing 6 and the square body 45 formed as a separate body is retrofitted to the motor housing 6, the square body 45 is formed as a separate body from the motor housing 6. Sufficient strength can be ensured in the body 45.

In addition, with this configuration, the square body 45 is formed to have a substantially trapezoidal shape when viewed from the side. This ensures that the square body 45 has sufficient strength.

Further, according to this configuration, the main base 2x is integrally molded by aluminum die casting. This also applies to the sub-base 2y. Therefore, accuracy can be ensured in the material itself in the sub-base 2y. Further, the sub-base 2y can be manufactured with good dimensional accuracy. Therefore, when the sub-base 2y is assembled to the main base 2x, it is possible to ensure that the sliding surfaces 2xx and 2yy of both bases 2x and 2y are flush with each other.

Further, according to this configuration, the bosses 2x1 are provided in pairs on the main base 2x. Each of the bosses 2x1 has a recess 2x2 opened on the right side. The sub-base 2y is provided with a pair of bosses 2y1 facing the pair of bosses 2x1 of the main base 2x. An insertion hole 2y2 having a step 2y4 into which a thumbscrew 2z can be inserted is formed in the boss 2y1 so as to be concentric with the screw hole 2x3 of the recess 2x2 of the main base 2x. A cylindrical convex portion 2y3 is press-fitted into the insertion hole 2y2 so as to protrude from the exit side. Then, by inserting each convex portion 2y3 of the paired boss 2y1 of the sub-base 2y into each concave portion 2x2 of the paired boss 2x1 of the main base 2x, the sub-base 2y can be assembled to the main base 2x. ing. The vertical length of the concave portion 2x2 is slightly larger than the vertical length (diameter) of the convex portion 2y3. Therefore, when this insertion is performed, the sub base 2y can be vertically positioned with respect to the main base 2x at the same time as this insertion. Therefore, when the sub-base 2y is assembled to the main base 2x, it is possible to easily ensure that the sliding surfaces 2xx and 2yy of both bases 2x and 2y are flush with each other. As a result, the ease of assembling the sub-base 2y to the main base 2x can be improved.

Further, according to this configuration, the main base 2x is provided with the recesses 2x2 in pairs in the front and rear. Further, the sub-base 2y is provided with a pair of convex portions 2y3 in the front and rear so as to face the concave portions 2x2 of the main base 2x. That is, these recessed portions 2x2 and convex portions 2y3 are provided at two locations, front and rear. Therefore, the sub-base 2y assembled to the main base 2x does not tilt in the front-rear direction. Therefore, the accuracy of the longitudinal inclination of the sub-base 2y assembled to the main base 2x can be easily achieved.

Further, according to this configuration, the convex portion 2y3 is formed of a sleeve that can be inserted into the concave portion 2x2 of the main base 2x. A thumbscrew 2z is inserted into the O-ring 2y5 and the sleeve, which is the convex portion 2y3, from each insertion hole 2y2 of the paired boss 2y1 of the sub-base 2y. Therefore, the member for vertically positioning the sub-base 2y with respect to the main base 2x (the recess 2x2 and the protrusion 2y3) and the thumbscrew 2z can be implemented in an integrated structure.

Further, according to this configuration, the insertion hole 2y2 of the sub-base 2y has a cylindrical convex portion that protrudes from the exit side with the O-ring 2y5 inserted from the exit side (left side) to the step 2y4. A 2y3 sleeve is press-fitted. At this time, the thumbscrew 2z is press-fitted into the O-ring 2y5. Therefore, the inserted knob screw 2z can be made difficult to come out from the O-ring 2y5. Therefore, the thumbscrew 2z can be prevented from falling out of the insertion hole 2y2 of the boss 2y1.

Further, according to this configuration, the recess 2x2 of the main base 2x is formed in the shape of a long hole whose longitudinal direction is the longitudinal direction. Therefore, the pitch error between the front and rear convex portions 2y3 provided on the sub-base 2y can be absorbed. This is particularly effective when the angular plate 35 is constructed as a separate member from the base 2 and is assembled so as to be mutually adjustable.

Further, according to this configuration, the fixing screw for assembling the sub-base 2y to the main base 2x is a thumb screw 2z that can be operated by picking it up with the operator's fingers. Therefore, the sub-base 2y can be attached and detached without requiring any tools.

Further, according to this configuration, the sliding surface 2yy (lower surface) of the sub-base 2y is made flat by mechanical cutting. Therefore, the flatness of this sliding surface 2yy can be increased.

Further, according to this configuration, the surface of the sub-base 2y is subjected to surface treatment by nickel plating. Therefore, the hardness of the surface of the sub-base 2y can be increased. Therefore, it is possible to suppress unevenness that occurs on the sliding surface 2yy of the sub-base 2y due to friction.

The above content is merely one embodiment of the present invention, and does not mean that the present invention is limited to the above content.

In each embodiment, the portable circular saw 1 has been described as an example of a portable cutting machine. However, it is not limited to this, and a cutter, jigsaw, etc. may be used.

In the embodiment, the square body 45 has been described as an example of the protrusion. However, the shape is not limited to this, and the protrusion may have a shape such as a polygonal pyramid (triangular pyramid, quadrangular pyramid, etc.), a polygonal prism, a cone, a cylinder, or the like. Further, in the embodiment, the shape of the square body 45 has been described as approximately trapezoidal in side view. However, the shape is not limited to this, and may be substantially triangular in side view.

Furthermore, in the embodiment, the square body 45 is formed integrally with the motor housing 6. However, the present invention is not limited to this, and the square body 45 may be formed separately from the motor housing 6. In that case, the square body 45 will be fixed to the motor housing 6 with a fastening member (screw, claw, etc.).

Further, in the embodiment, a configuration in which the first corner 46a of the square body 45 protrudes from the motor housing 6 has been described. However, the present invention is not limited to this, and the first corner 46a of the square body 45 may be configured to protrude from the base 2 or the handle housing 7. Furthermore, although a configuration has been described in which the handle protrudes upward from the motor housing 6, a configuration in which it protrudes leftward from the side surface of the handle housing 7 may also be used.

Further, in the embodiment, a configuration has been described in which the tip 36a of the lever 36 is one of the three points required to turn the portable circular saw 1 upside down. However, the present invention is not limited to this, and the front end of the base 2 or the angular plate 35 may be one of the three points necessary to turn the portable circular saw 1 upside down. This is because the position of the tightening operation of the lever 36 determines which of the three points, the tip 36a of the lever 36, the front end of the base 2, or the angular plate 35, will be one of the three points required to turn the portable circular saw 1 upside down. This is because it can change depending on the

Furthermore, in the embodiment, a configuration has been described in which the convex portion 2y3 and the thumbscrew 2z are provided on the sub-base 2y. However, the present invention is not limited to this, and a configuration in which the convex portion 2y3 and the thumbscrew 2z are provided on the main base 2x may be used. Further, the convex portion 2y3 may be provided on the sub-base 2y, and the thumbscrew 2z may be provided on the main base 2x. Further, the convex portion 2y3 may be provided on the main base 2x, and the thumbscrew 2z may be provided on the sub-base 2y.

In the embodiment, in the description of the procedure for assembling the sub-base 2y to the main base 2x, each convex portion 2y3 of the paired boss 2y1 of the sub-base 2y is inserted into each concave portion 2x2 of the paired boss 2x1 of the main base 2x. I explained the configuration to include. However, the present invention is not limited to this, and in the explanation of the procedure for assembling the sub-base 2y to the main base 2x, each convex portion 2y3 of the paired boss 2y1 of the sub-base 2y is attached to the paired boss 2x1 of the main base 2x. A structure in which each recess 2x2 is inserted may also be used.

Furthermore, in the embodiment, the sub-base 2y is assembled to the main base 2x using the thumbscrew 2z, which can be operated by picking it up with the operator's fingers. However, the present invention is not limited to this, and the assembly of the sub-base 2y to the main base 2x may be performed using wing bolts that can be operated by pinching them with the fingers of an operator.

Furthermore, in the embodiment, a configuration has been described in which the concave portion 2x2 of the main base 2x and the convex portion 2y3 of the sub-base 2y are formed at two locations, front and rear. However, the present invention is not limited to this, and the recess 2x2 of the main base 2x and the protrusion 2y3 of the sub-base 2y may be formed in three or more locations in the front and rear.

Furthermore, in the embodiment, a configuration has been described in which the sub-base 2y is assembled in the left-right direction with respect to the main base 2x. However, the present invention is not limited to this, and the sub-base 2y may be assembled in the vertical direction with respect to the main base 2x (see FIG. 16).

The main base 2x and the sub-base 2y may be made of sheet metal or synthetic resin having rigidity. In that case, appropriate machining is required to ensure that the sliding surfaces 2xx, 2yy of both bases 2x, 2y are flush with each other.

1 Portable circular saw (portable cutting machine)
2 Base 2a Top surface 2b Sliding surface 2c Front edge 2d Rear edge 2x Main base 2x1 Boss 2x2 Recess 2x3 Screw hole 2xx Sliding surface 2y Sub-base 2y1 Boss 2y2 Insertion hole 2y3 Convex portion 2y4 Step 2y5 O-ring 2y6 Front position line 2y7 Rear position line 2yy Sliding surface 2z Pick screw 3 Circular saw body 4 Electric motor 4a Stator 4b Rotor 4c Sensor board 5 Saw blade (cutting tool)
6 Motor housing 6a Inlet port 7 Handle housing 7a Gripping part 8 Gear housing 8a Fixed cover 8b Screw hole 8c Guide bolt 8d Ring material 8e Compression spring 8f Lever 8g Nut 9 Drive shaft 10 Bearing 11 Bearing 12 Cooling fan 13 No. 1 gear 14 Intermediate Shaft 15 Bearing 16 Bearing 17 2nd gear 18 3rd gear 19 Final shaft 20 Bearing 21 Bearing 22 Bearing box 23 Shaft 23a Outer surface 24 4th gear 25 Bolt 26 Lock-off button 26a Left operating section 26b Right operating section 26c Inclined surface 27 Controller 28 Baffle plate 29 Duct 30 Power source 31 Battery pack 32 Bracket 33 Support shaft 35 Angular plate 35a Support shaft 35b Guide groove 35c Fixing screw 35d Fixing screw 36 Lever 38 Angular plate 39 Depth guide 39a Guide groove 40 Guide part 41 Trigger 45 Square body 46 Top surface 46a First corner 47 Front surface 47a Recess 48 Right front slope 48a Recess 49 Left surface 49a Recess 50 Movable cover 51 Insertion hole 52 Inner peripheral surface 53 Tension spring 54 Reverse tilt switching lever 55 Fixing screw 56 Torsion spring 62 Fastening member 63 Head 63a Hexagonal hole 70 Sliding plate 71 Plate body 72 Guide body 71a Lower surface 72 Guide body 73 Vertical wall 73a Insertion hole 74 Horizontal wall 75 Resin sheet C Cutting site E Ground

Claims (8)

A portable cutting machine using an electric motor as a drive source,
a handle extending upward from the front of the cutting machine main body and connected to the rear of the cutting machine main body;
a trigger provided on the inner peripheral surface of the handle portion so as to be movable in the vertical direction;
a lock button that is movable in the left and right directions with respect to the handle portion and that cooperates with locking the trigger;
The lock button has an end portion protruding from the handle portion in the left-right direction, and the end portion has an inclined surface that gradually moves away from the handle portion downward from an upper end of the lock button, and a lower end of the shoe is located further from the handle than the upper end ;
A portable cutting machine having an R curved surface around the entire circumference of the inclined surface . The portable cutting machine according to claim 1,
The lock button is located above the trigger of the portable cutting machine. The portable cutting machine according to claim 1 or 2,
The lock button is a portable cutting machine that moves between a protruding position in which the entire inclined surface protrudes from the handle portion and a housing position in which the entire inclined surface is accommodated within the handle portion. The portable cutting machine according to claim 1,
The lock button has a right end portion having the inclined surface and a left end portion having the inclined surface. The portable cutting machine according to claim 4,
The lock button is a portable cutting machine that integrally includes a left button having the inclined surface, a right button having the inclined surface, and an intermediate portion in which the left button is attached to the left end and the right button is attached to the right end. . The portable cutting machine according to claim 5,
In the portable cutting machine, the middle part of the lock button has a cylindrical shape that moves straight in the left-right direction. The portable cutting machine according to claim 5 or 6,
The right button and the left button are located at the same distance from the handle when the lock button is in a neutral position,
The lock button is movable in either the left or right direction with respect to the neutral position. A portable cutting machine according to any one of claims 1 to 7,
The lock button is a portable cutting machine that releases the locked state of the trigger by moving in the left and right direction.

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