JP6881134B2 - Electric tool - Google Patents

Description

The present invention relates to, for example, a power tool that operates using a battery as a power source.

For example, in a battery-powered cordless desktop cutting machine, the wiring inside the housing mainly consists of a power line that supplies power from the battery to the motor and a signal line for monitoring and controlling the operation of the motor with a controller. Have. The controller detects the state of the motor that rotates by the electric power from the battery with a sensor, receives the output via the signal line, and controls the operation of the motor.

Patent No. 5924492

Since the battery is usually mounted on the outer peripheral surface of the housing away from the motor, the length of the power line from the battery to the motor becomes long, and the influence of noise generated from the power line may not be negligible. Further, since the space inside the housing is small, the power line and various signal lines may be wired so as to be adjacent to each other over a long section. For this reason, the signal line may pick up noise generated from the power line, and due to the influence of this noise, the controller may misidentify the signal from the motor and malfunction.

Further, in order to suppress the noise generated from the power line, it is necessary to provide a large-capacity capacitor in the circuit inside the housing.

An object of the present invention is to provide a highly reliable power tool that prevents a malfunction of a controller due to noise generated in a power line.

The power tool of the present invention comprises a motor housed in a housing to rotate a disk-shaped cutting blade, a power source held in the housing, a power line for supplying electric power from the power source to the motor, and rotation of the motor. The housing includes a control unit for controlling, a first storage unit having a power supply holding unit for storing the motor and the power line and holding the power supply, and a second storage unit for storing the control unit. The first storage portion and the second storage portion are separated from each other.

With the above configuration, the length of the power line between the power supply and the motor can be shortened, so that the amount of noise generated from the power line can be reduced. Further, since the control unit is housed in the second storage unit separated from the first storage unit that stores the power line and is not arranged in the space where the power line is located, the influence of noise generated from the power line can be reduced. Therefore, it is possible to prevent a malfunction of the control unit. Further, for controlling the motor, the length of the signal line connecting the control unit and the motor and the power line in parallel can be shortened, and the influence of noise generated from the power line on the signal line can be suppressed.

Preferably, the base having a mounting surface on which the material to be cut can be placed, the cutting portion having the cutting blade, the motor and the housing, and one end portion of the base are erected to shake the cutting portion. Further comprising a support portion that is movably supported and brought close to or separated from the above-mentioned mounting surface, the motor has an output shaft extending in a direction intersecting the side surface of the cutting blade, and the power supply is the above-mentioned power source. The control unit is located on the side opposite to the previously described mounting surface with respect to the motor, the control unit is located on the side opposite to the previously described mounting surface with respect to the output shaft of the motor, and the first housing unit and the support Located between the department.

With the above configuration, the power supply and the control unit are located on the side opposite to the mounting surface of the base with respect to the motor. Therefore, when the support unit is provided so as to be tiltable with respect to the mounting surface, the power supply or the control unit supports the motor. The support portion can be tilted at a large angle with respect to the mounting surface without interfering with the tilting of the portion with respect to the mounting surface.

Preferably, the support portion has a slide pipe that slidably supports the cut portion, and the cut portion is within a shadow region formed when the cut portion is projected by a light beam parallel to the longitudinal direction of the slide pipe. Includes the shadow of the slide pipe. With this configuration, the shadow of the slide pipe is included in the shadow area of the battery or the housing, and the slide pipe does not come off the housing and pop out in the direction orthogonal to the longitudinal direction of the slide pipe. Both can be configured compactly.

Preferably, the power supply has a guide rail for mounting on the housing, the housing has a rail receiving portion that engages with the guide rail, and the extending direction of the rail receiving portion is the output shaft. Orthogonal to the longitudinal direction of. Normally, the guide rail of the power supply is formed along the longitudinal direction of the power supply. Therefore, due to the above configuration, when the support portion stands upright with respect to the base, the power supply protrudes from the lateral direction of the housing, resulting in a large cut portion. It is possible to suppress the conversion.

Preferably, when the cut portion is fixed to the support portion for transportation and the cut portion is fixed by the means, the extending direction of the rail receiving portion of the housing is the slide. Approximately orthogonal to the longitudinal direction of the pipe. With this configuration, the force acting on the slide pipe when the power supply is mounted on the housing is in a direction substantially orthogonal to the longitudinal direction of the slide pipe, and hardly acts in the direction along the slide pipe. Therefore, when the power supply is mounted on the housing, it is possible to prevent the cut portion from sliding on the slide pipe.

Preferably, the slide pipe comprises a pair of pipes whose longitudinal directions are substantially parallel to each other, and the extending direction of the rail receiving portion of the housing is substantially parallel to the surface including the center of each of the paired pipes. is there. With this configuration, the force acting on the pair of slide pipes when the power supply is mounted on the housing is parallel to the plane passing through the center of the pipe, and one slide pipe rotates around the other slide pipe. It does not help to make you. Therefore, it is possible to suppress the occurrence of distortion such as rotation of the slide pipe due to this force.
The present invention further controls the rotation of a motor housed in a housing to rotate a disk-shaped cutting blade, a power source held in the housing, a power line for supplying electric power from the power source to the motor, and rotation of the motor. The cutting portion is erected from one end of the control unit, a base having a mounting surface on which the material to be cut can be placed, the cutting blade, the motor, and the housing, and the cutting portion. The housing comprises a support portion that swingably supports between the top dead point located at the uppermost position and the bottom dead point located at the lowermost position and is brought close to or separated from the above-described mounting surface. It has a first storage unit having a power supply holding unit that stores the motor and the power line and holds the power supply, and a second storage unit that stores the control unit, and the first storage unit and the first storage unit. The motor is separated from the two storage portions, the motor has an output shaft extending in a direction intersecting the side surface of the cutting blade, and the power supply is the motor when the cutting portion is located at the bottom dead point. The control unit is located on the side opposite to the previously described mounting surface, and the control unit is on the opposite side of the previously described mounting surface with respect to the output shaft of the motor when the cutting portion is located at the bottom dead point. Provided is an electric tool characterized in that it is located in and between the first storage portion and the support portion.

According to the power tool of the present invention, it is possible to shorten the power line to suppress the generation of noise and prevent the motor from malfunctioning due to the noise generated from the power line.

A side view of a single-tilt type tabletop cutting machine according to the first embodiment of the present invention. The front view of the desktop cutting machine shown in FIG. FIG. 3 is a cross-sectional view of line segments III-III of the desktop cutting machine shown in FIG. FIG. 2 is a cross-sectional view of a housing for line segments IV-IV of the desktop cutting machine shown in FIG. A side view of a double-tilt type tabletop cutting machine according to a second embodiment of the present invention. The front view of the desktop cutting machine shown in FIG. FIG. 5 is a vertical cross-sectional view of line segments VII-VII of the desktop cutting machine shown in FIG. FIG. 5 is a cross-sectional view of line segments VIII-VIII of the desktop cutting machine shown in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The same or equivalent components, members, processes, etc. shown in the drawings are designated by the same reference numerals, and duplicate description will be omitted as appropriate.

The single-tilt type tabletop cutting machine 1 according to the first embodiment as the power tool of the present invention will be described with reference to FIGS. 1 to 4. As shown in FIG. 1, the desktop cutting machine 1 is mainly composed of a base portion 2, a support portion 3, and a cutting portion 4. A disk-shaped saw blade 41 is attached to the cutting portion 4 as a cutting blade, and the cutting portion 4 can tilt in a direction orthogonal to the side surface of the saw blade 41 with respect to the base portion 2, and further, the cutting portion 2 has a disc-shaped saw blade 41. On the other hand, the saw blade 41 is configured to swing in the direction of approaching or separating.

The base portion 2 is mainly composed of a base 21 that can be placed on a floor surface or the like, a turntable 22 supported on the base 21, and a fence 23 provided on the base 21. The upper surface of the turntable 22 is substantially flush with the upper surface of the base 21, and the turntable 22 is rotatably connected to the base 21 with the center of the base 21 as a rotation axis. Both the upper surface of the base 21 and the turntable 22 form a mounting surface 21A on which the material W to be cut is placed. Further, the turntable 22 and the base 21 are formed with a groove portion (not shown) into which the saw blade 41 enters when the cutting portion 4 is lowered.

The fences 23 are paired as shown in FIG. 2, and each includes a holding surface 23A substantially orthogonal to the upper surface of the base 21. When cutting the material W to be cut, one surface of the material W to be cut is brought into contact with the pressing surface 23A of the fence 23.

An operation unit 24 for performing a rotation operation and a rotation position fixing operation of the turntable 22 is provided on the front portion of the turntable 22. The operation unit 24 can rotate the turntable 22 around the rotation axis of the base 21 and fix it at an arbitrary angle. A tilting shaft 25 and a protruding portion 26 are provided at the rear portion of the turntable 22. The tilt shaft 25 extends in the front-rear direction so that its central axis coincides with the upper surface of the turntable 22. The protruding portion 26 projects upward and has an elongated hole 26a (FIG. 2) formed in an arc shape about the central axis of the tilting shaft 25.

The support portion 3 is erected upward at the rear portion of the turntable 22, and is tiltably attached to the turntable 22 about the tilting shaft 25, and the mounting surface 21A from the upper end portion of the holder 31. Two slide pipes 32 and 33 fixedly supported in parallel with the slide pipe 32 and 33, a slider 34 slidably provided with respect to the slide pipes 32 and 33, and a swing that swingably connects the cutting portion 4 to the slider 34. It includes a shaft 35.

Since the lower portion of the holder 31 is rotatably provided around the tilting shaft 25, the holder 31 can be tilted in the left-right direction of the turntable 22. The rear portion of the turntable 22 is an example of one end portion of the base 21.

A screw hole 31a is formed in the holder 31 at a position corresponding to the elongated hole 26a, and the clamp lever 36 is screwed into the screw hole 31a. Specifically, the threaded portion of the clamp lever 36 penetrates the elongated hole 26a and is screwed into the screw hole 31a. By operating the clamp lever 36 in the release direction, the pressing force on the surface of the protruding portion 26 of the clamp lever 36 is released, so that the holder 31 can be tilted around the tilt shaft 25 within the arc length range of the elongated hole 26a. It becomes. On the other hand, by operating the clamp lever 36 in the fixing direction, a pressing force is applied from the clamp lever 36 to the surface of the protruding portion 26, so that the holder 31 is fixed to the protruding portion 26 at a desired inclination angle. To. As a result, the holder 31 is fixed to the turntable 22, so that so-called inclined cutting becomes possible.

A stopper (not shown) that is a positioning means when tilted is provided on the side surface portion of the holder 31 on the base portion 2 side, and a stopper bolt (not shown) is located on the upper surface of the turntable 22 on the movement locus of the stopper and is screwed. It has been stopped. When the holder 31 is tilted with respect to the turntable 22 about the tilting shaft 25, the stopper abuts on the head of each of the stopper bolts at a predetermined tilting angle, and the tilting position of the cutting portion 4 is positioned. In the present embodiment, the state in which the holder 31 stands upright with respect to the mounting surface 21A is set to an inclination angle of 0 degrees, and the state in which the holder stands upright. One stopper bolt is provided so as to engage with one stopper when the holder 31 is tilted to a position of 0 to 45 degrees to the left. The other stopper bolt is provided so as to engage with the other stopper when the holder 31 is tilted to a position of 5 degrees to the right from 0 degrees. Therefore, in the present embodiment, it is possible to cut the slope from 45 degrees to the left to 5 degrees to the right.

Further, one of the slide pipes 32 and 33 extends in a direction parallel to the mounting surface 21A of the base 21 and orthogonal to the rotation axis of the saw blade 41. The other slide pipe 33 extends parallel to the slide pipe 32 and is located below the slide pipe 32 in the upright state of the holder 31. The slide pipes 32 and 33 have substantially the same length as each other, and a connecting member 37 is attached to their front ends. The slide pipes 32 and 33 can change the position of the cutting portion 4 with respect to the holder 31, and the cutting operation can be performed at a desired position with respect to the material W to be cut mounted on the mounting surface 21A.

The cutting portion 4 includes a saw blade 41, a motor 42 for rotating the saw blade 41, a power transmission mechanism 43 provided between the motor 42 and the saw blade 41, and a battery pack 5 for supplying electric power to the motor 42. Be prepared. Further, the cutting portion 4 has a housing 60 for accommodating the motor 42 and the power transmission mechanism 43.

The rear end of the housing 60 is connected to the slider 34 via a swing shaft 35. In the present embodiment, the swing shaft 35 is a shaft extending in a direction orthogonal to the side surface of the saw blade 41. The housing 60 is rotatable about the swing shaft 35 with respect to the slider 34, and is swingable in a direction closer to or away from the base 21. A spring (not shown) is provided around the swing shaft 35 of the slider 34, and the spring urges the cutting portion 4 to swing in the direction (upward) away from the base portion 2 by the saw blade 41. There is. Therefore, unless a downward force is applied to the operation handle 61 provided on the front upper portion of the housing 60, the cut portion 4 swings upward most by the stopper mechanism (not shown) provided around the swing shaft 35. It is stopped at the position and maintained at this position. In the present invention, the position is referred to as "top dead center". Further, the operation handle 61 is provided with a switch 62 for switching on / off of the motor 42.

On the other hand, by applying a downward force to the operation handle 61, the cutting portion 4 swings downward with the swing shaft 35 as a fulcrum against the urging force of the spring, so that the cutting process can be performed. When the cutting portion 4 is swung downward, the saw blade 41 penetrates into the groove portion of the turntable 22 and is stopped by a stopper mechanism (not shown) at a position where a predetermined amount has penetrated. In the present invention, the position is referred to as "bottom dead center". Therefore, in the desktop cutting machine 1 shown in FIG. 1, the cutting portion 4 is located at the bottom dead center.

As shown in FIG. 3, the housing 60 includes a saw cover 63 that covers a part of the outer periphery of the saw blade 41, a saw blade shaft portion 44 that is connected to the saw cover 63 and serves as a rotation center of the saw blade 41, and a power transmission mechanism 43. It is composed of a main housing 64 for accommodating the control unit 45 and a motor housing 65 connected to the side surface of the main housing 64 for accommodating the motor 42. Since the operation handle 61 is integrally provided on the main housing 64, the operation handle 61 swings the main housing 64 around the swing shaft 35 to move the saw blade 41 toward the base 21. Becomes possible.

Inside the saw cover 63, a saw cover 66 (FIG. 3) having a shape covering the outer peripheral portion of the saw blade 41 protruding from the saw cover 63 is rotatably provided. When the cutting portion 4 is at the top dead center, the saw cover 66 rotates to a position that covers the outer circumference of the saw blade 41 protruding from the saw cover 63. On the other hand, the saw cover 66 is housed in the saw cover 63 by a link mechanism (not shown) in a state where the cut portion 4 is swinging downward.

The main housing 64 is provided with a battery mounting portion 64A to which the battery pack 5 as a power source is mounted, and a power line 67 is wired from the battery mounting portion 64A to the motor 42 to supply electric power to the motor 42. In addition to the operation handle 61, the main housing 64 is provided with a transport handle 68 for transporting the entire desktop cutting machine. The battery mounting unit 64A is an example of a power supply holding unit.

The motor housing 65 includes a split housing in which two split pieces are put together and integrated, and the motor 42 is housed therein. One end of the motor housing 65 in the longitudinal direction communicates with the main housing 64, and the other end is provided with a slit-shaped air window 65a for cooling the motor 42.

Further, as shown in FIG. 2, since the motor housing 65 is arranged on the side surface of the main housing 64, the slide pipes 32 and 33 slidably support the housing 60 including the motor housing 65 and the main housing 64. When the tabletop cutting machine 1 is viewed from the front to the rear, the shadows of the slide pipes 32 and 33 are included in the projection area of the housing 60 and do not protrude from the housing 60. Therefore, the cutting portion 4 including the slide pipes 32 and 33 can be compactly configured.

The motor 42 has a cooling fan 46 attached to the output shaft 42A and is connected to the saw blade shaft portion 44 via a power transmission mechanism 43, so that the saw blade 41 is rotated in conjunction with the rotation of the motor 42. There is. In the present embodiment, the power transmission mechanism 43 is composed of gears. Further, when the motor 42 rotates, the cooling fan 46 is rotated and the cooling air is taken into the motor housing 65 through the air window 65a to cool the motor 42 and the power transmission mechanism 43. Further, in order to detect the operating state of the motor 42, a stator substrate 47 is provided near the end on the opposite side of the output shaft 42A. The stator substrate 47 and the control unit 45 are electrically connected by a signal line 48.

The battery pack 5 has a plurality of battery cells such as a secondary battery cell inside, and outputs electric power corresponding to the desktop cutting machine 1. The battery pack 5 has a plurality of terminals in which the battery case 51 has a rectangular parallelepiped shape, and a substantially rectangular surface facing the battery mounting portion 64A serves as a mounting surface whose longitudinal direction is the mounting direction to the battery mounting portion 64A. It has 52. Further, a pair of guide rails 53 for mounting on the battery mounting portion 64A are formed on the mounting surface.

On the other hand, the battery mounting portion 64A of the main housing 64 is formed with a rail receiving portion 64B to which the guide rail 53 of the battery pack 5 is engaged. When the guide rail 53 of the battery pack 5 engages with the rail receiving portion 64B and the mounting on the battery mounting portion 64A is completed, the terminal 52 of the battery pack 5 and the corresponding terminal portion of the main housing 64 are electrically connected. Then, power can be supplied from the battery pack 5 to the motor 42.

Next, the positional relationship between the battery pack 5, the motor 42, and the control unit 45 with respect to the housing 60 will be described with reference to FIGS. 3 and 4. In the following description, the orientation of up / down, left / right, or front / back is based on the premise that the cutting portion 4 is at bottom dead center.

As shown in FIGS. 3 and 4, in the housing 60, the motor housing 65 is attached to the main housing 64 so as to be located on the lower right side of the main housing 64. Further, the motor 42 is housed in the motor housing 65 so that the output shaft 42A faces the side surface side of the saw blade 41 and is orthogonal to the side surface of the saw blade 41 as shown in FIG. A stator substrate 47 is located near the other end of the motor 42 and constitutes a part of the motor 42.

In the present embodiment, the reason why the motor housing 65 is arranged below the main housing 64 is that the tilt angle of the cut portion 4 is eliminated by eliminating the parts that interfere with the tilt of the cut portion 4 with respect to the base 21. This is to widen the range and increase the degree of freedom for inclined cutting. That is, the cutting performance is ensured by the configuration in which no separate component is provided below the motor housing 65. In FIG. 4, the plane including the output shaft 42A of the motor 42 in the plane and parallel to the mounting surface 21A when the cutting portion 4 is at the bottom dead center is shown by L1.

The battery pack 5 is attached to the upper side of the motor housing 65 in the main housing 64. Therefore, the battery pack 5 is located on the side opposite to the mounting surface 21A with respect to the motor 42, that is, the surface L1. Therefore, the battery mounting portion 64A is located above the motor housing 65 in the housing 60. Further, as shown in FIG. 3, a power line 67 extending from the terminal of the battery mounting portion 64A to the stator substrate 47 is wired in the motor housing 65. Further, a wiring 70 connecting the terminal of the battery mounting portion 64A and the switch 62 is also provided, and by operating the switch 62, power supply from the battery pack 5 to the motor 42 via the stator substrate 47 is started. ing. The motor housing 65 is an example of the first storage portion of the housing 60.

The control unit 45 is arranged in the main housing 64 in the control unit storage unit 69 which is partitioned above the surface L1 and behind the motor 42. The signal line 48 is wired from the control unit 45 to the stator substrate 47 via the control unit storage unit 69. The control unit storage unit 69 is an example of the second storage unit.

Since the control unit storage unit 69 is provided at the rear portion of the main housing 64, while the motor housing 65 is located on the lower right side of the main housing, the control unit storage unit 69 and the motor housing 65 are spatially mutually exclusive. It is separated.

With the above configuration, since the battery pack 5 is mounted on the main housing 64 so as to be adjacent to the motor housing 65, the length of the power line 67 itself connecting the battery pack 5 and the motor 42 can be shortened. That is, by providing the battery mounting portion 64A in the motor housing 65 accommodating the motor 42, the battery pack 5 and the motor 42 can be arranged close to each other, and the power line 67 can be shortened. As described above, since the length of the power line 67 through which a relatively large current flows is short, the absolute amount of noise generated from the power line 67 can be reduced. Although the desktop cutting machine 1 is a large tool as a whole, it is necessary to densely collect the electric parts related to the control of the motor 42 around the motor 42 of the cutting portion 4, and the noise from the power line 67 to other parts needs to be concentrated. The impact tends to be large. Therefore, the desktop cutting machine 1 is a power tool that is particularly effective in reducing noise generated from the power line 67. Further, the power supply is not limited to the battery pack 5, and may be a power cord for inputting an AC power supply.

Further, since the motor housing 65 is attached to the lower right side of the main housing 64 and the control unit storage unit 69 is located behind the inside of the main housing 64, the power line 67 wired in the motor housing 65 and the control unit storage unit are stored. The signal lines 48 wired to the unit 69 rarely run in parallel with each other in the main housing 64 when they come out of the motor housing 65 or the control unit housing unit 69, respectively. Therefore, it is possible to suppress interference with the signal flowing through the signal line 48 due to the noise generated from the power line 67. Therefore, the influence of noise on the signal line 48 can be reduced, and the malfunction of the control unit 45 that operates based on the output from the signal line 48 can be suppressed.

Further, by arranging the battery pack 5 above the motor 42 and arranging the control unit 45 behind the motor 42, the power line 67 extending from the battery pack 5 to the motor 42 is arranged so as to extend mainly in the vertical direction. At the same time, the signal line 48 extending from the control unit 45 to the motor 42 can be arranged so as to extend mainly in the front-rear direction. With such an arrangement, it is possible to reduce the region where the power line 67 and the signal line 48 extend side by side, that is, the region where the power line 67 and the signal line 48 run side by side, and suppress the influence of noise on the signal line 48 of the power line 67. can do.

Further, both the power line 67 and the signal line 48 are electrically connected to the stator board 47, but immediately after the wiring comes out from the stator board 47, the power line 67 extends upward toward the battery mounting portion 64A. On the other hand, since the wiring of the signal line 48 extends laterally toward the control unit 45, the parallel running section of the power line 67 and the signal line 48 can be shortened, and interference of the power line 67 with the signal line 48 due to noise can be suppressed. ..

A capacitor may be provided in the power supply circuit to the motor 42 in order to suppress fluctuations in the current flowing from the battery pack 5 to the motor 42.

Further, since the mounting direction of the battery pack 5 and the longitudinal direction of the output shaft 42A of the motor 42 are substantially orthogonal to each other, it is possible to prevent the battery case 51 from protruding from both ends in the left-right direction of the motor housing 65. Therefore, it is possible to prevent the housing 60 to which the battery pack 5 is mounted from becoming large and to make the cut portion 4 compact.

Further, when the cutting portion 4 is at the bottom dead center, the mounting direction of the battery pack 5 with respect to the main housing 64 is a substantially vertical direction. Since this mounting direction is substantially orthogonal to the longitudinal direction of the slide pipes 32 and 33, the sliding of the cut portion 4 with respect to the slide pipes 32 and 33 at the time of mounting or attaching / detaching the battery pack 5 to the main housing 64 is suppressed. That is, it is possible to prevent the cut portion 4 from unexpectedly sliding when the battery pack 5 is attached to and detached from the housing 60.

Further, since the mounting direction of the battery pack 5 is parallel to the surface including the two slide pipes 32 and 33, the rotation of the other slide pipe 32 with respect to one slide pipe 33 when the battery pack 5 is mounted or attached / detached. Suppress. Therefore, it is possible to suppress the parallelism of the two slide pipes from being out of order and to suppress a decrease in accuracy at the time of cutting.

Next, the double-tilt type tabletop cutting machine 100, which is the second embodiment of the power tool of the present invention, will be described with reference to FIGS. 5 to 8. In the following description, parts that are the same as or equivalent to the parts constituting the single-tilt type tabletop cutting machine 1 according to the first embodiment are designated by the same reference numerals, and duplicate description will be omitted as appropriate.

The desktop cutting machine 100 shown in FIG. 5 can perform inclined cutting in either the right direction or the left direction. Therefore, one stopper bolt constituting the positioning means for fixing and supporting the tilting position of the holder 31 is engaged with the one stopper when the holder 31 is tilted to the left at a position of 0 to 45 degrees. It is provided in. The other stopper bolt is provided so as to engage with the other stopper when the holder 31 is tilted to a position of 45 degrees to the right from 0 degrees. Therefore, in the present embodiment, it is possible to cut the slope from 45 degrees to the left to 45 degrees to the right.

The cutting portion 104 includes a saw blade 141, a motor 142 for rotating the saw blade 141, a belt drive mechanism 143 provided between the motor 142 and the saw blade 141, and a battery pack 105 for supplying electric power to the motor 142. Be prepared. Further, the cutting portion 104 has a housing 160 for accommodating the motor 142 and the belt drive mechanism.

The housing 160 of the cutting portion 104 includes a saw blade shaft portion 144 that covers a part of the outer periphery of the saw blade 141 and is a rotation center of the saw blade 141, a main housing 164 that houses a belt drive mechanism 143 and a control portion 145, and a main housing. It is configured with a motor housing 165 that is connected to 164 and houses the motor 142. As shown in FIGS. 5 and 7, the motor housing 165 is located above the main housing 164 when the cutting portion 104 is at bottom dead center. In the motor housing 165, the motor 142 is arranged so that the output shaft 142A is parallel to the left-right direction.

A battery mounting portion 164A to which the battery pack 105 as a power source is mounted is provided in front of the upper part of the main housing 164, and a power line 167 is wired from the battery mounting portion 164A to the motor 142 to supply power to the motor 142. ..

The motor housing 165 is composed of a split housing in which two split pieces are put together and integrated, and the motor 142 is housed therein. One end of the motor housing 165 in the longitudinal direction communicates with the main housing 164, and the other end is provided with a slit-shaped air window 165a for cooling the motor 142.

The motor 142 has a cooling fan 146 attached to the output shaft 142A and is connected to the saw blade shaft portion 144 via the belt drive mechanism 143, so that the saw blade 141 is rotated in conjunction with the rotation of the motor 142. There is. Further, when the motor 142 rotates, the cooling fan 146 is rotated and the cooling air is taken into the motor housing 165 through the air window 165a to cool the motor 142 and the belt drive mechanism 143. Further, in order to detect the operating state of the motor 142, a stator substrate 147 is provided near the end on the opposite side of the output shaft 142A.

The battery pack 105 has a plurality of battery cells such as a secondary battery cell, and outputs electric power corresponding to the desktop cutting machine 100. The battery pack 105 has a plurality of terminals in which the battery case 151 has a rectangular parallelepiped shape, and the substantially rectangular surface facing the battery mounting portion 164A serves as a mounting surface whose longitudinal method is the mounting direction to the battery mounting portion 164A. It has 152. Further, a pair of guide rails 153 for mounting on the battery mounting portion 164A is formed on the mounting surface.

On the other hand, the battery mounting portion 164A of the main housing 164 is formed with a rail receiving portion 164B to which the guide rail 153 of the battery pack 105 is engaged. When the guide rail 153 of the battery pack 105 engages with the rail receiving portion 164B and the mounting on the battery mounting portion 164A is completed, the terminal 152 of the battery pack 105 and the corresponding terminal portion of the main housing 164 are electrically connected. Then, power can be supplied from the battery pack 105 to the motor 142.

Next, the positional relationship between the battery pack 105, the motor 142, and the control unit 145 in the housing 160 will be described below with reference to FIG. 7. In the following description, the vertical, horizontal, or front-back orientation will be described on the premise that the cut portion is at bottom dead center.

As shown in FIG. 7, in the housing 160, the motor housing 165 is attached to the main housing 164 so as to be located above the main housing 164. Further, the motor 142 is housed in the motor housing 165 so that the output shaft 142A provided at one end thereof is orthogonal to the side surface of the saw blade 141. As shown in FIG. 8, a stator substrate 147 is attached near the other end of the motor 142 to form a part of the motor 142.

The reason for arranging the motor housing 165 above the main housing 164 is to eliminate parts that interfere with the tilting of the cutting portion 104 with respect to the base 21 so that the base 21 has a wide angle range in both the left and right directions. This is to enable inclined cutting in which the holder 31 is inclined.

The battery pack 105 is attached to the front side of the motor housing 165 with respect to the main housing 164. Therefore, the battery mounting portion 164A is provided on the front surface of the motor housing 165 in the housing 160. Further, as shown in FIG. 8, a power line 167 extending from the terminal of the battery mounting portion 164A to the stator substrate 147 is wired in the motor housing 165. Further, 170 wirings connecting the terminal of the battery mounting portion 164A and the switch 62 are also provided, and the power supply to the motor 142 is started by operating the switch 62. The motor housing 165 is an example of the first storage portion of the housing 160.

The control unit 145 is arranged in the main housing 164 in the control unit storage unit 169 which is virtually partitioned below the motor housing 165. The signal line 148 is arranged from the control unit 145 toward the stator substrate 147. The control unit storage unit 169 is an example of the second storage unit.

The control unit storage unit 169 is provided at the rear portion of the main housing 164, while the motor housing 165 is mounted on the lower right side of the main housing 164, so that the control unit storage unit 169 and the motor housing 165 are separated from each other. Has been done.

With the above configuration, since the battery pack 105 is mounted adjacent to the motor housing 165, the length of the power line 167 itself connecting the battery pack 105 and the motor 142 can be shortened. Since the length of the power line 167 through which a relatively large current flows is short, the absolute amount of noise generated from the power line 167 can be reduced.

Further, since the motor housing 165 is located above the main housing 164 and the control unit storage unit 169 is located inside and behind the main housing 164, the power line 167 wired in the motor housing 165 and the control unit storage unit The signal lines 148 wired to 169 have almost no length of running in parallel in the main housing 164 in close proximity to each other when exiting from the motor housing 165 or the control unit housing 169, respectively. Therefore, it is possible to suppress interference with the signal flowing through the signal line 148 due to the noise generated from the power line 167. Therefore, since noise does not appear on the output from the signal line 148, it is possible to prevent a malfunction of the control unit 145 that operates based on the output from the signal line 148.

Further, both the power line 167 and the signal line 148 are connected to the stator substrate 147, but immediately after the wiring comes out from the stator substrate 147, the power line 167 extends upward toward the battery mounting portion 164A, while the wiring extends upward. Since the wiring of the signal line 148 extends laterally toward the control unit 145, the parallel running section of the power line 167 and the signal line 148 can be shortened, and interference of the power line 167 with the signal line 148 due to noise can be suppressed.

1 Desktop cutting machine, 5 Power supply, 41 Cutting blade, 42 Motor, 45 Control unit, 60 housing, 65 Motor housing, 67 Power line, 69 Control unit storage unit

Claims (5)

A motor that is housed in a housing and rotates a disk-shaped cutting blade,
The power supply held in the housing and
A power line that supplies power from the power source to the motor,
A control unit for controlling the rotation of said motor,
A base with a mounting surface on which the material to be cut can be placed,
A cutting portion having the cutting blade, the motor, and the housing,
It stands upright from one end of the base and supports the cut portion swingably between the top dead center located at the uppermost position and the bottom dead center located at the lowermost position with respect to the above-mentioned mounting surface. Supports that are close to or separated from each other
With
The housing is
A first storage unit having a power supply holding unit that stores the motor and the power line and holds the power supply, and a first storage unit.
It has a second storage unit that stores the control unit , and has
The first storage portion and the second storage portion are separated from each other .
The motor has an output shaft extending in a direction intersecting the side surface of the cutting blade.
The power supply is located on the side opposite to the above-described mounting surface with respect to the motor when the cutting portion is located at the bottom dead center.
The control unit is located on the side opposite to the above-described mounting surface with respect to the output shaft of the motor when the cutting portion is located at the bottom dead center, and the first accommodating portion and the supporting portion. power tool characterized that you located between. The support portion has a slide pipe that slidably supports the cut portion.
Electric tool according to claim 1, wherein the the shadow area as possible when the cut portion is projected in the longitudinal direction and parallel rays of the slide pipe includes a shadow of the slide pipe. The power supply has a guide rail for mounting on the housing.
The housing has a rail receiving portion that engages with the guide rail.
The power tool according to claim 2 , wherein the extending direction of the rail receiving portion is orthogonal to the longitudinal direction of the output shaft. It has a means for fixing the cut portion to the support portion for transportation.
The power tool according to claim 3 , wherein when the cut portion is fixed by the means, the extending direction of the rail receiving portion of the housing is substantially orthogonal to the longitudinal direction of the slide pipe. The slide pipe consists of a pair of pipes whose longitudinal directions are substantially parallel to each other.
The power tool according to claim 3 or 4 , wherein the extending direction of the rail receiving portion of the housing is substantially parallel to a surface including the center of each of the paired pipes.

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