JP2017205891A - Portable processing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric processing machine such as a portable cutter that is moved with a base brought into contact with a processing material to perform cutting processing and that is enabled to obtain high slidability in a variety of situations at low cost, according to the present invention since a problem of increase in cost arises as it is difficult to obtain high slidability for a processing material having a high water content when conventional fluorine coating is carried out so as to slidability of a base for a processed material and a slide plate made of ultrahigh-molecular weight polyethylene needs to be replaced wholly owing to damage when fitted to a base lower surface.SOLUTION: A slide plate 100 having sheet materials 102-105, made of ultrahigh-molecular weight polyethylene, stuck on a fitting plate 101 is fitted detachably to a base lower surface. The slide plate 100 can be easily detached when not necessary, and only a sheet material having been damaged is replaced to lower costs.SELECTED DRAWING: Figure 17

Description

  The present invention relates to a portable processing machine such as a cutting machine used for cutting a cutting material such as wood.

  2. Description of the Related Art Some portable cutting machines used for cutting wood or the like have a form in which cutting is performed by placing the cutting material on the upper surface of the cutting material and allowing the user to move it by hand. This type of cutting machine includes a base that is brought into contact with the upper surface of the cutting material, and a cutting machine body that is supported on the upper surface side of the base. The cutting machine body includes an electric motor and a cutting tool that rotates using the electric motor as a drive source. The cutting tool protrudes toward the cutting material contact surface, which is the lower surface of the base. The cutting material can be cut by moving the cutting machine and cutting the cutting material while rotating the cutting tool protruding from the lower surface by bringing the base into contact with the upper surface of the cutting material.

  Thus, in this type of cutting machine, since the user operates the cutting machine to move along the upper surface of the cutting material, it is possible to ensure high slidability of the base with respect to the upper surface of the cutting material. This is significant from the viewpoint of improving the operability of moving and thus the workability. The following patent document discloses a device for improving the slidability of the base material to be cut. Patent Document 1 discloses a technique for improving the slidability by applying a fluorine coating to the lower surface of the base. Patent Document 2 discloses a technique for improving slidability by detachably attaching a fluorine-coated plate along the lower surface of a base. Patent Document 3 discloses a technique for improving the slidability by attaching a plate made of polymer polyethylene along the lower surface of the base. Patent Document 4 discloses a technique for improving the slidability by directly attaching a polyethylene sheet material to the lower surface of the base.

JP 2006-26886 A JP 2006-289869 A JP 2001-315075 A Japanese Patent Laid-Open No. 2015-136873

  According to the technique disclosed in each of the above patent documents, the slidability of the base with respect to the cutting material can be increased to improve the workability of the cutting machine, but there are also the following problems to be improved. A configuration in which a fluorine coating is directly applied to the lower surface of the base or a sheet material is pasted cannot cope with a case where high slidability is not required, and the usability of the cutting machine may be impaired. In addition, in the fluorine coating, when the moisture content of the cutting material is high, the slidability is lowered, so that there is a problem that the workability is lowered in the cutting operation of the wet cutting material. Furthermore, according to the technology for improving the slidability by attaching a high molecular polyethylene plate to the lower surface of the base, it is necessary to replace the entire plate when it is replaced due to scratches or the like, so that the maintenance cost increases. There was a problem.

  The present invention has been made in view of the above-described conventional problems. In the technique for improving the slidability of the base to the workpiece, it can be removed when not necessary, and is also high for a wet cutting material. An object is to achieve slidability and to reduce the maintenance cost because only the damaged part needs to be replaced.

  The above-described problems are solved by the following inventions. A first invention is a sliding plate that is detachably attached to a workpiece contact surface that is a lower surface of a base of a portable electric processing machine, and is a sliding plate on which a highly slidable sheet material is attached. .

  According to the first invention, the sliding plate can be removed from the base when unnecessary. Moreover, since it is the structure which affixed the sheet | seat material, high slidability is exhibited also with respect to a workpiece with high moisture content like a fluorine coating. Furthermore, it is sufficient to replace only the damaged sheet material, and it is not necessary to replace the entire sliding plate, so that the maintenance cost can be reduced.

  According to a second invention, in the first invention, the sliding plate is a sliding plate in which a sheet material is attached to the lower surface of the mounting plate, and an end portion of the sheet material is bent to the upper surface side. .

  According to the second aspect of the invention, it is possible to prevent the sheet material from peeling off from the mounting plate and maintain high slidability over a long period of time.

  According to a third aspect of the present invention, in the second aspect, the end portion of the sheet material is folded back to the upper surface, and the sliding plate is configured such that the folded portion is sandwiched between the mounting plate and the base when attached to the base. It is.

  According to the third invention, it is possible to more reliably prevent the end portion of the sheet material from peeling off from the mounting plate and maintain high slidability over a long period of time.

  4th invention is the sliding plate located in the recessed part provided in the upper surface of the attachment board in the 3rd invention.

  According to the fourth aspect of the invention, it is possible to prevent a gap from being generated between the base and the mounting plate by sandwiching the folded portion of the sheet material.

  A fifth invention is the sliding plate according to any one of the second to fourth inventions, wherein the sheet material is bent toward the upper surface side in accordance with the uneven shape in the surface direction of the end portion of the mounting plate.

  According to 5th invention, the edge part of the attachment board has the uneven | corrugated shape of a surface direction according to the edge part of a base. The sheet material is bent to the upper surface side in conformity with the concave and convex shape so as not to block the concave portion of the mounting plate, so that the function of the concave portion and thus the concave portion in the surface direction of the base is not impaired. Yes.

  According to a sixth invention, in the fifth invention, the sheet material is divided into a plurality of sheets according to the uneven shape of the mounting plate, and the end portion of each sheet material is folded to the upper surface side according to the uneven shape. It is a moving plate.

  According to 6th invention, the edge part of a sheet | seat material can be match | combined easily with the uneven | corrugated shape of the edge part of a mounting plate. In addition, by dividing the sheet material into a plurality of sheets according to the uneven shape of the end of the mounting plate, the end of the sheet material is matched with the uneven shape of the end of the mounting plate, and the end is clearly cleaned The sheet material can be bent to the side, and the peeling of the sheet material can also be prevented in this respect.

  A seventh invention is the sliding plate of any one of the first to sixth inventions, wherein the sheet material is made of ultrahigh molecular weight polyethylene.

  According to the seventh aspect, it is possible to exhibit the high slidability of the sliding plate even for a processed material having a high moisture content.

  An eighth invention is a portable electric processing machine in which a sliding plate according to any one of the first to seventh inventions is attached to a base.

  According to the eighth invention, by attaching the sliding plate to the base of the portable processing machine, it is possible to ensure high slidability with respect to the workpiece, thereby improving the workability of the portable processing machine. be able to. According to the eighth invention, the sliding plate can be retrofitted in order to enhance the slidability of the portable processing machine, and the applicable range of the sliding plate can be expanded. By obtaining the sliding plate according to the eighth aspect of the invention, it is possible to quickly and easily take measures against slidability for a portable processing machine having a base on which such measures against slidability are not applied.

It is a whole perspective view of the cutting machine concerning this embodiment. It is a (II) arrow line view in Drawing 1, and is a right view of a cutting machine. It is a (III) arrow line view in Drawing 2, and is a top view of a cutting machine. FIG. 4 is a front view of the cutting machine, as viewed from (IV) in FIG. 2. It is a right view of a cutting machine. In this figure, it has shown with the cutting tool removed. FIG. 3 is a sectional view taken along line (VI)-(VI) in FIG. 2 and is a longitudinal sectional view of the cutting machine. It is a top view of a cutting machine. In this figure, in order to show the flow of cooling air in an easy-to-understand manner, a part of the cross section is broken. FIG. 4 is a right side view of the handle portion, taken along line (VIII)-(VIII) in FIG. 3. This figure is shown with all the divided parts of the housing cover attached. FIG. 4 is a right side view of the handle portion, taken along line (VIII)-(VIII) in FIG. 3. This figure is shown with the first and third divided portions of the housing cover removed. FIG. 4 is a right side view of the handle portion, taken along line (VIII)-(VIII) in FIG. 3. This figure is shown in a state where all the divided parts (the right half part) of the housing cover are removed from the left half part. It is a perspective view of a base. In this figure, the ruler fixing part is shown in an exploded manner. FIG. 4 is a cross-sectional view taken along line (XII)-(XII) in FIG. 3 and is a vertical cross-sectional view of a ruler fixing portion. It is a side view of the cutting machine of a suspended state. It is a (XIV) arrow line view of FIG. 13, Comprising: It is a front view of the cutting machine of a suspended state. It is a whole side view of a cutting machine. In this figure, it has shown in the state which attached the sliding plate to the base lower surface. It is a perspective view of a sliding plate. This figure has shown the state seen from the upper surface side. It is a bottom view of a sliding plate. It is the (XVIII) part enlarged view in FIG. This figure has shown the periphery of the front-end part of a base and a sliding plate. It is a figure which shows the outline of a circuit.

  Next, an embodiment of the present invention will be described with reference to FIGS. In this embodiment, as an example of a portable processing machine, a cutting machine 1 called a so-called portable marnoko is illustrated. In the following description, with respect to the front-rear direction of the members, configurations, and the like, the direction in which cutting proceeds (cutting progress direction) is the front side. A user is located behind the cutting machine 1. Accordingly, the left and right directions of the members and the like are used with reference to the user. The left side is also called the back side, and the right side is also called the front side.

  As shown in FIGS. 1 to 4, the cutting machine 1 includes a base 10 that is brought into contact with the upper surface of the cutting material W, and a cutting machine body 20 that is supported on the upper surface side of the base 10. The base 10 has a substantially rectangular flat plate shape. The lower surface of the base 10 is a workpiece contact surface 10 a that contacts the cutting material W. The base 10 is provided with a window portion 10b for projecting the cutting tool 22 toward the workpiece contact surface 10a. The window portion 10 b is formed in a rectangular shape that is long in the front-rear direction along the right edge side of the base 10. Guide portions 10c and 10d for aligning the cutting tool 22 with the smear line are provided at the front portion and the rear portion of the base 10, respectively. A front support portion 11 and a rear support portion 12 are provided at two locations on the top and bottom of the base 10. The front side support part 11 and the rear side support part 12 are provided in a state of rising upward in parallel with each other. The cutting machine body 20 is supported via the front support part 11 and the rear support part 12 so as to be tiltable to the left and right.

  A tilting plate 14 is supported by the front support portion 11 via a left / right tilt support shaft 13 so as to be tiltable to the left and right. The tilting position of the tilting plate 14 with respect to the front support portion 11 is fixed by tightening the thumbscrew 16. The front portion of the cutter cover 21 of the cutting machine body 20 is supported on the right end portion side of the tilt plate 14 via the vertical tilt support shaft 15. As shown in FIG. 3, a tilting plate 18 is supported on the rear support portion 12 via a left and right tilt support shaft 17 so as to be tiltable to the left and right. The rear left / right tilt support shaft 17 is disposed coaxially with the front left / right tilt support shaft 13. The tilting position of the tilting plate 18 with respect to the rear support portion 12 is fixed by tightening the thumbscrew 19. The tilt plate 18 supports the rear side of the blade cover 21 via a cut depth adjusting mechanism 70 described later. When the front and rear thumb screws 16 and 19 are loosened, the cutting machine body 20 can be tilted left and right about the left and right tilting shafts 13 and 17. By tilting the cutting machine body 20 left and right (mainly in the direction in which the upper part is displaced to the right), the cutting angle of the cutting tool 22 with respect to the cutting material W can be changed to perform so-called inclined cutting.

  The cutting machine main body 20 decelerates the rotary output of the circular cutting tool 22, the cutting tool cover 21 that mainly covers the periphery of the cutting tool 22 on the upper side, the electric motor 30 as a drive source for rotating the cutting tool 22, and the electric motor 30. For this purpose, a reduction gear part 40 for the purpose and a handle part 50 held by the user are provided. The upper half of the upper edge of the blade 22 is covered by the blade cover 21. The cutting tool 22 protrudes to the lower surface side through a window portion 10 b provided in the base 10. The lower side of the cutting tool 22 protruding to the lower surface side of the base 10 is covered with a movable cover 23. The movable cover 23 is supported so as to be openable and closable along the periphery of the blade 22. The movable cover 23 is spring-biased in the closing direction (counterclockwise direction in FIG. 2). As shown in FIG. 2, the movable cover 23 is opened in a direction (clockwise direction in FIG. 2) that is pushed by the end face of the cutting material W and exposes the cutting edge of the cutting tool 22. An opening / closing lever 23 a is provided at the rear of the movable cover 23. The movable cover 23 can be opened by a user by manually grasping the opening / closing lever 23a.

  The electric motor 30 is coupled to the back side (left side) of the blade cover 21 via the reduction gear unit 40. As the electric motor 30, a brushless motor using a commercial 100V AC power supply 68 as a power source is used. As shown in FIG. 6, the electric motor 30 includes a stator 32 fixed to the motor case 31 side and a rotor 33 that is rotatably supported on the inner peripheral side of the stator 32. A sensor substrate 34 having a magnetic sensor for detecting the rotational position of the rotor 33 is attached to the back side (left side) of the stator 32. The motor shaft 35 coupled to the rotor 33 is rotatably supported around the shaft via two bearings 35a and 35b disposed on the output side and the counter-output side in the motor axis J direction. The bearing 35 a on the output side in the motor axis J direction is held by the gear case 43. The bearing 35 b on the opposite side to the motor axis J direction is held at the center of the back surface of the motor case 31.

  A cooling fan 36 is attached to the motor shaft 35. A baffle plate 36 a for efficiently generating a wind flow is disposed on the back side (left side) of the cooling fan 36. The opening of the motor case 31 is closed by this baffle plate 36a. When the electric motor 30 is started, the cooling fan 36 on the motor shaft 35 rotates integrally. As shown in FIG. 7, a plurality of intake windows 37 are provided on the back side (left side) of the motor case 31. When the cooling fan 36 rotates, outside air (motor cooling air) is introduced into the motor case 31 through the intake window 37. The outside air that has flowed into the motor case 31 flows to the output side in the motor axis J direction while cooling the stator 32, the rotor 33, the sensor substrate 34, and the like.

  As shown in FIG. 7, a ventilation hole 38 is provided on the side of the cooling fan 36 and on the rear surface side of the motor case 31. A portion of the outside air (motor cooling air) that has cooled the interior of the motor case 31 flows into the controller housing 60 through the vent 38. The controller housing 60 is a substantially rectangular bottom shallow case in plan view, and is integrally provided on the rear surface side of the motor case 31. As shown in FIG. 3 and FIG. 7, the controller housing portion 60 protrudes to the left in substantially the same manner as the motor case 31. A controller 61 for controlling the operation of the electric motor 30 is accommodated in the controller accommodating portion 60. The controller 61 has a configuration in which a control board is accommodated in a shallow controller case made of aluminum die cast and resin-molded. The motor cooling air that has flowed into the controller housing 60 is exhausted from the exhaust hole 63 through the air passage 62 provided on the right side of the controller housing 60 as indicated by a thick solid arrow (A) in the drawing. The controller 61 having a heat source such as an FET (field effect transistor) or a diode bridge is cooled by the motor cooling air flowing into the controller housing 60. The controller 61 includes a rectifier circuit including a diode bridge for rectifying a current supplied from a power source, a control circuit including a microcomputer that transmits a control signal based on position information of the rotor 33 detected by the sensor board 34, A drive circuit composed of an FET that switches the current of the electric motor 30 based on a control signal received from the control circuit is mounted. A smoothing circuit composed of an electrolytic capacitor 67 for smoothing the rectified current is not mounted on the controller 61 but mounted in a capacitor case 66 described later.

  One ventilation port 39 is provided on the side of the cooling fan 36 and also on the front side of the motor case 31. A duct 65 is connected to the vent hole 39. The duct 65 extends forward along the back side of the blade cover 21. The front end of the duct 65 reaches the side of the cutting site. As shown by a thick solid arrow (B) in FIG. 7, a part of the motor cooling air that has cooled the inside of the motor case 31 is blown out from the vent hole 39 toward the guide portion 10 c through the duct 65. Dust such as cutting powder accumulated near the guide portion 10c is blown off by the motor cooling air blown out from the duct 65. By blowing off the dust in the vicinity of the guide portion 10c, the visibility of the guide portion 10c is increased and the cutting operation can be performed accurately and quickly. The remaining motor cooling air that does not flow into any of the vents 38 and 39 is blown out into the blade cover 21 through the gear case 43. Dust such as cutting powder generated at the cutting site is blown off by the motor cooling air blown into the blade cover 21.

  As shown in FIGS. 1 and 2, an arrow 21 a indicating the rotation direction of the blade 22 is displayed on the front side of the blade cover 21. In FIG. 2, the blade 22 rotates counterclockwise as indicated by an arrow 21a. For this reason, dust, such as cutting powder, is blown upward by the momentum of the cutting tool 22 rotating at the cutting site. The dust blown up into the blade cover 21 from the cutting part is collected as it is to the rear side in the blade cover 21 by the momentum of the blade 22.

  The rotational output of the electric motor 30 is decelerated through the reduction gear unit 40 and transmitted to the spindle 41. A first driven gear 46 is engaged with a drive gear portion 35 c provided at the tip of the motor shaft 35. The first driven gear 46 is fixed to the intermediate shaft 47. The intermediate shaft 47 is rotatably supported by the gear case 43 via two bearings 47a and 47b arranged on the output side and the non-output side in the motor axis J direction behind and below the motor shaft 35. A second driven gear 48 is integrally provided on the intermediate shaft 47. A third driven gear 49 is meshed with the second driven gear 48. The third driven gear 49 is fixed to the spindle 41.

  The rotational output of the electric motor 30 is transmitted to the spindle 41 after being decelerated in two stages through meshing between the drive gear portion 35c and the first driven gear 46 and meshing between the second driven gear 48 and the third driven gear 49. . The spindle 41 protrudes inside the blade cover 21. A circular cutting tool 22 is attached to the tip of the spindle 41 protruding into the cutting tool cover 21. The cutting tool 22 is fixed by a cutting tool fixing screw 42 fastened to the tip end surface of the spindle 41. The spindle 41 is rotatably supported via two bearings 44 and 45 disposed on the output side and the non-output side in the motor axis J direction with respect to the gear case 43 in front and below the intermediate shaft 47.

  As shown in FIG. 1, the handle portion 50 has a loop shape (mountain shape) straddling between the upper portion of the electric motor 30 and the upper surface of the controller housing portion 60. The handle portion 50 is disposed at the center of gravity of the cutting machine 1 with respect to the position of the cutting machine 1 in the left-right direction (the direction of the motor axis J of the electric motor 30). For this reason, when the center of gravity of the cutting machine 1 is located below the handle part 50, the user can hold the handle part 50 and carry the cutting machine 1 in a balanced manner in the left-right direction.

  The handle portion 50 is a side surface provided with a standing portion 51 that rises upward from the vicinity of the coupling portion between the electric motor 30 and the reduction gear portion 40, and a grip portion 52 that is inclined downward from the upper portion of the standing portion 51. It has a sight mountain shape. An upright portion 51 is provided so as to incline in a direction descending forward from the topmost portion of the mountain shape when viewed from the side, and a grip portion 52 is provided in a direction descending rearward from the topmost portion. The user uses the cutting machine 1 by gripping the grip portion 52 that descends to the rear side (user side). The rear part of the grip part 52 is coupled to the upper surface of the controller housing part 60. In the following description, the controller accommodating portion 60 is also regarded as a part constituting a part of the handle portion 50 as necessary. In this case, the handle portion 50 includes a standing portion 51, a grip portion 52, and a controller housing portion 60, and has a loop shape extending from the upper surface to the rear surface of the electric motor 30.

  A power cord 55 is drawn into the rear part of the grip part 52. The power cord 55 is inserted through the rubber protective tube 55a attached to the rear portion of the grip portion 52 and drawn therein. As shown in FIG. 19, when the plug 55c of the power cord 55 is connected to a power outlet 69 for AC 100V, the electric motor 30 receives power from the AC power source 68 and the cutting machine 1 can be activated. In this specification, the plug 55c of the power cord 55 is inserted into the power outlet 69 and mechanically connected, or in the case of the DC power type, the battery pack is mechanically connected to the battery mounting portion of the apparatus. A state in which a power source is connected to the main circuit (a circuit connecting the power source and the electric motor 30) and a current flows through the main circuit by operating the power source operation member 53 is referred to as a “power source connection state”. When the power supply operation member is activated in the power connection state, a current flows through the main circuit (power is supplied), the electric motor 30 is activated, and thus the cutting machine is activated.

  A power indicator lamp 56 for notifying the power connection state is provided on the upper front surface of the standing portion 51. As shown in FIG. 19, when the plug 55c of the power cord 55 is inserted into the power outlet 69 and mechanically connected, the power indicator lamp 56 is lit even when the power operation member 53 is not operated. In addition to the function of notifying the connection state of the power cord 55 to the power outlet 69, the power indicator lamp 56 of the present embodiment is a function of notifying that it cannot be restarted after being stopped (restart prevention state). The electric motor 30 has a function of reporting an overload state and a temperature abnormality. In the present embodiment, the power indicator 56 uses an LED (light emitting diode) as a light source. These various states are visually notified by changing the color of the power indicator lamp 56, switching between the lighting state and the blinking state, and changing the blinking speed.

  Conventionally, as disclosed in, for example, Japanese Patent Application Laid-Open No. 2005-349699, there has been a case where a power indicator that notifies a power connection state is provided on the side of the handle portion and on the blade cover 21 side. When the handle portion is arranged closer to the blade cover side by using a brushless motor whose machine direction is compact as the motor 30, there is a problem that the visibility of the energizing lamp is lowered. In this regard, the power indicator lamp 56 of the present embodiment is provided not on the side of the handle portion 50 but on the front side of the grip portion 52 held by the user and at a site that can be seen from the front of the upright portion 51 and from above. Therefore, high visibility from the side and above of the power indicator lamp 56 is ensured while the handle portion 50 is disposed closer to the blade cover 21.

  A lighting switch 54 is provided on the right side of the standing portion 51. As shown in FIG. 2, a lighting tool 24 is provided on the front side of the back side of the blade cover 21. When the illumination switch 54 is turned on, the illumination tool 24 is turned on. When the illuminator 24 is turned on, the cutting site is brightly illuminated and cutting work such as in a dark place can be performed efficiently.

  On the inner peripheral side (lower surface side) of the handle portion 50 and on the upper lower surface of the grip portion 52, there is provided a trigger-type power operation member 53 that the user pulls upward with the fingertip of the hand holding the grip portion 52. It has been. The power supply operation member 53 is supported via a support shaft 53a so that it can be tilted up and down. When the power operation member 53 is pulled upward while the power indicator lamp 56 is lit (power supply connected state), the switch body 58 built in the grip portion 52 is turned on. When the switch body 58 is turned on, the electric motor 30 is activated and the blade 22 rotates. When the pulling operation is released, the power supply operation member 53 is returned to the off position by the spring biasing force of the compression spring 53b (see FIGS. 9 and 10). When the power operation member 53 is returned to the off position, the switch body 58 is turned off and the electric motor 30 is stopped.

  On the upper side of the power supply operation member 53, a lock-on button 57 is provided. The lock-on button 57 is provided on both the left and right sides of the handle portion 50. When the lock-on button 57 is pushed while the power supply operation member 53 is pulled upward, the electric motor 30 is locked in the activated state. In this lock-on state, it is not necessary for the user to continue pulling and operating the power supply operation member 53, so that a long-time work can be easily performed, thereby improving workability. The lock-on state is released by pulling the power operation member 53 upward again.

  On the other hand, even in this lock-on state, if the power supply is cut off due to a power failure or the plug 55c of the power cord 55 being unintentionally disconnected from the power outlet 69, the electric motor 30 naturally stops. The electric motor 30 is not started at the stage where the power failure is recovered without releasing the lock-on state or the plug 55c of the power cord 55 is connected to the power outlet 69 again, thereby preventing an inadvertent restart. Power supply control is made. This power control state (restart prevention state) is notified by the power indicator lamp 56 blinking in red, for example. The restart prevention state is canceled by once pulling the power operation member 53 upward. After releasing the restart prevention state in this way, the electric motor 30 is started when the power supply operation member 53 is again pulled upward.

  As shown in FIGS. 1, 3, 4, and 6, the handle cover 59 that forms the outline of the handle portion 50 has a left half portion 59L as viewed from the left-right direction orthogonal to the operation direction (front-rear direction) of the power supply operation member 53. And a right and left halved portion 59R are connected to each other. In FIGS. 1, 3, 4, and 6, a reference D is attached to the mutual abutment surface of the left half portion 59L and the right half portion 59R.

  As shown in FIG. 10, the left half portion 59 </ b> L is integrally formed across the motor case 31 and the controller housing portion 60. As shown in FIG. 10, the power operation member 53, the illumination switch 54, the lock-on button 57, and the switch body 58 are attached to the left half portion 59L. In addition, a protective tube 55a with a power cord 55 inserted through the rear portion of the left half portion 59L is screwed with two fixing screws 55b.

  The right half portion 59R is screwed to the left half portion 59L. As shown in FIG. 8, the right half portion 59R is further divided into three division portions 59R1, 59R2, and 59R3. The right half portion 59R includes a first divided portion 59R1 extending from the standing portion 51 to the grip portion 52, a second divided portion 59R2 corresponding to the right side portion of the controller accommodating portion 60, and a lower portion corresponding to the lower portion of the standing portion 51. It is divided into three parts of three division parts 59R3. An almost entire region of the outer surface of the first divided portion 59R1 is covered with an elastomer resin layer for the purpose of preventing slipping and absorbing shock. In the present embodiment, the divided areas of the first to third divided portions 59R1, 59R2, and 59R3 are set with the coating area of the elastomer resin layer as a boundary. The second and third divided portions 59R2 and 59R3 correspond to regions where the elastomer resin layer is not covered. The exhaust port 63 described above is provided at the rear of the second divided portion 59R2. The first to third divided portions 59R1, 59R2, and 59R3 are individually screwed to the left half portion 59L (joint portion). Therefore, the first to third divided portions 59R1, 59R2, and 59R3 can be detached from the left half portion 59L by individually removing screws. In FIG. 8, each range of the first to third division parts 59R1, 59R2, 59R3 is indicated by a thick solid line.

  FIG. 8 shows a state in which the first to third divided portions 59R1, 59R2, 59R3 are all attached to the left half portion 59L. FIG. 9 shows a state in which the first and third divided portions 59R1 and 59R3 are removed while the second divided portion 59R2 is attached. FIG. 10 shows a state in which all of the first to third divided portions 59R1, 59R2, and 59R3 (the entire right half portion 59R) are removed from the left half portion 59L. In this state, all of the internal components such as the illumination switch 54, the power supply operation member 53, the switch body 58, the holding portion of the power cord 55, the controller 61, and the like are exposed from the front side.

  Although not shown in the drawing, with the second and third divided portions 59R2 and 59R3 attached to the left half portion 59L, only the first divided portion 59R1 is removed, whereby the illumination switch 54 and the power supply operation member 53 are removed. The switch body 58 and the like are exposed so that inspection and replacement work can be performed. Further, by removing only the first divided portion 59R1, the power cord 55 can be inspected and replaced. When inspecting and replacing these various members, it is sufficient to remove only the first divided portion 59R1 while leaving the second and third divided portions 59R2 and 59R3 as they are. As a result, even if the gap (work space) between the two is narrow, the inspection and replacement work can be easily performed as compared with the case where the entire right half portion 59L is removed. Thus, the maintainability of the cutting machine 1 can be improved.

  Although not shown in the figure, if the motor case 31 is separated from the blade cover 21 side to avoid interference between the second divided portion 59R2 and the cut depth adjusting mechanism 70, the first and first By removing only the second divided portion 59R2 with the three divided portions 59R1 and 59R3 attached, the controller 61 is exposed and the inspection and replacement work can be performed. Also, by removing only the third divided portion 59R3 with the first and second divided portions 59R1 and 59R2 attached, the wiring and connectors between the lighting switch 54 and the lighting fixture 24 are exposed, and the inspection and replacement thereof are performed. Work can be done. Also in these cases, since it is sufficient to remove the split part 59R1 (or 59R2 or 59R3) only from the necessary part from the left half part 59L, various members of the right part half part 59R are removed. Inspection and replacement work can be performed efficiently in a small space.

  As shown in FIGS. 1 to 3, a cord hook portion 64 for hooking the power cord 55 is provided at the rear portion of the handle portion 50 and the rear portion of the first divided portion 59R1. By hooking the power cord 55 to the cord hook portion 64, it is possible to change the drawing direction (handling direction) of the power cord 55 from the rear to the side. By changing the drawing direction of the power cord 55 to, for example, the left direction, the user can efficiently perform the cutting work without the power cord 55 being in the way. The surface of the cord hook portion 64 is covered with an elastomer resin layer. This elastomer resin layer prevents the power cord 55 from slipping. In addition, by hooking the power cord 55 to the cord hook portion 64, it is possible to prevent unreasonable bending of the power cord 55 on the drawer base end side and to prevent disconnection.

  As shown in FIGS. 1, 3, 4, and 7, a capacitor case 66 is attached to the front surface of the motor case 31. A large electrolytic capacitor 67 is accommodated in the capacitor case 66. By disposing the electrolytic capacitor 67 separately from the controller 61, the controller 61 and the controller housing 60 can be made compact mainly in the height direction.

  Between the base 10 and the cutting machine body 20, the above-described cutting depth adjusting mechanism 70 is provided. The cutting depth adjusting mechanism 70 has a function of adjusting the cutting depth with respect to the cutting material W by changing the protruding amount of the cutting tool 22 to the lower surface side of the base 10. As shown in FIG. 3, the cut depth adjusting mechanism 70 is interposed between the tilting plate 18 provided on the base 10 side and the rear side of the blade cover 21.

  The cut depth adjusting mechanism 70 includes an arcuate depth guide 71 supported on the upper surface of the rear portion of the base 10. The depth guide 71 is supported by the tilt plate 18 so as to be tiltable back and forth. As shown in FIGS. 5 and 6, the depth guide 71 is provided with an arc-shaped guide groove hole 71a. A fixing screw shaft 73 is inserted through the guide groove hole 71a. The fixing screw shaft 73 is fastened to the back surface of the blade cover 21. A fixing lever 72 as an operation unit is attached to the head side of the fixing screw shaft 73. When the fixing lever 72 is operated to loosen the fixing screw shaft 73, the cutting machine body 20 can be tilted up and down around the vertically tilting support shaft 15. By tilting the cutting machine main body 20 up and down, the protruding amount (cutting depth) of the cutting tool 22 to the lower surface side of the base 10 changes. When the fixing screw 72 is operated in the reverse direction and the fixing screw shaft 73 is tightened, the vertical tilting position of the cutting machine body 20 is fixed, and the cutting depth of the cutting tool 22 with respect to the cutting material W is fixed.

  As shown in FIG. 3, the cut depth adjusting mechanism 70 is disposed between the rear portion of the blade cover 21 and the handle portion 50. For this reason, the working space for the right side portion of the handle portion 50 is narrow especially in the vicinity of the cut depth adjusting mechanism 70. In this regard, as described above, the right half portion 59R of the handle portion 50 is divided into the first to third divided portions 59R1, 59R2, 59R3, and can be individually detached from the left half portion 59L. Therefore, the maintenance work of the switch main body 58 and the power cord 55 can be easily performed as compared with a configuration in which the entire right half portion 59R is removed as a whole. In particular, when the cut depth is adjusted to the maximum as shown in FIG. 3, the second divided portion 59R2 is positioned on the left side of the fixing lever 72 as the operation portion. In this case, it is difficult to remove the second divided portion 59R2, but since the first and third divided portions 59R1 and 59R3 can be easily removed, maintenance work for the switch body 58, the illumination switch 54, and the like can be performed. In this respect, the maintainability is enhanced as compared with the conventional configuration in which the right half is integrally removed.

  FIG. 11 shows the base 10 as a single unit. Two types of parallel rulers 81 and 82 can be selected and attached to the base 10. The short type parallel ruler 81 includes a short ruler main body 81a and one connecting bar 81b. The long-type parallel ruler 82 includes a long ruler main body 82a and two connecting bars 82b. The parallel rulers 81 and 82 abut the ruler bodies 81 a and 82 a arranged along the right side of the base 10 against the right end edge of the cutting material W, so that the cutting machine 1 is parallel along the right end edge of the cutting material W. It has a function to guide to. The parallel rulers 81 and 82 are fixed to the base 10 via connecting bars 81b and 82b, respectively.

  The base 10 is provided with ruler holding grooves 10e at two locations on the front and rear sides. The left and right end portions of the two ruler holding grooves 10e are opened at the left and right side portions of the base 10, respectively. The positions of the ruler bodies 81a and 82a can be finely adjusted by adjusting the positions (left and right direction positions) of the connecting bars 81b and 82b in the ruler holding groove 10e. The positions of the ruler bodies 81a and 82a are fixed by fixing the positions of the connecting bars 81b and 82b in the ruler holding groove 10e. In order to fix the positions of the connecting bars 81b and 82b, a ruler fixing portion 80 is provided in each of the ruler holding grooves 10e. The two ruler fixing portions 80 at the front and rear portions have the same configuration. Details of the ruler fixing portion 80 are shown in FIG.

  The ruler fixing portion 80 includes a fixing screw shaft 85, a ball bearing 86, a pressing member 87, and an operation member 88. The ruler fixing portion 80 of the present embodiment presses the pressing member 87 against the connecting bars 81b and 82b of the parallel ruler 80 by the propulsive force (screw tightening force) of the fixing screw shaft 85 generated by the rotation operation of the operation member 88, The ruler bodies 81 a and 82 a have a function of fixing the ruler bodies 81 a and 82 a at a fixed position with respect to the side of the base 10. The fixing screw shaft 85 is fastened in the fixing screw hole 10ff of the fixing base portion 10f provided in the base 10. An operation member 88 is attached to the head of the fixed screw shaft 85. The operation member 88 is fixed to the head of the fixed screw shaft 85 in a state in which the operation member 88 is prevented from rotating by the nut portion 85a and is prevented from coming off in the axial direction by the retaining ring 88a. When the operating member 88 is rotated, the fixing screw shaft 85 moves up and down. The pressing member 87 is pressed against the upper surfaces of the connecting bars 81b and 82b by the propulsive force when the fixing screw shaft 85 is displaced downward.

  A pressing member 87 as a friction reducing portion is attached to the lower part of the fixed screw shaft 85. The pressing member 87 is supported via a ball bearing 86 so as to be relatively rotatable around the axis of the fixed screw shaft 85. Although the ball bearing 86 is used in this embodiment, it may be changed to other rolling bearings such as a needle bearing and a roller bearing. The pressing member 87 is made of resin and has a cylindrical shape with a diameter sufficiently larger than the fixed screw shaft 85. A notch 87 a is provided in a part of the pressing member 87 in the circumferential direction. An elastic rubber rubber pin 84 driven into the fixed base portion 10f enters the notch portion 87a. The rubber pin 84 is pressed against the outer ring of the ball bearing 86. When the rubber pin 84 is pressed, rotation of the outer ring of the ball bearing 86 is restricted, and as a result, the pressing member 87 is prevented from rotating. Detachment of the pressing member 87 is restricted by a fixing nut 89 fastened to the lower portion of the fixing screw shaft 85. The lower part of the fixing screw shaft 85 and the fixing nut 89 are arranged so as not to protrude from the lower surface of the pressing member 87. When the fixing screw shaft 85 is tightened and moved downward, the pressing member 87 is integrally displaced and pressed against the upper surface of the connecting bar 81b (82b) of the parallel ruler 81 (82). At this time, the pressing member 87 is pressed against the connecting bar 81b (82b) while being prevented from rotating.

  Conventionally, as disclosed in, for example, Japanese Patent Application Laid-Open No. 2006-159786, the tip of the fixing screw is directly pressed against the connecting bar to fix the position of the parallel ruler. However, there is a problem that an indentation at the tip of the fixing screw remains. For this reason, when the fixing screw is pressed again thereafter, the indentation follows the tip of the fixing screw and the connecting bar is displaced, which makes it difficult to precisely adjust the position of the parallel ruler. . In this respect, according to the ruler fixing portion 80 of this embodiment, since the resin-made pressing member 87 that is prevented from rotating by the rubber pin 84 is pressed against the upper surface of the connecting bar 81b (82b), the connecting bar 81b. The damage (indentation) and displacement of (82b) can be prevented, and precise fine adjustment of the ruler bodies 81a and 82a can be performed.

  Further, for example, according to the ruler fixing structure disclosed in JP2013-248740A, the above-described indentation remains on the connecting bar because the support member is pressed in contact with the surface by tightening the fixing screw. However, since the problem of the displacement of the connecting bar due to the friction caused by the surface contact of the support member has not been solved, it has been difficult to precisely fine-tune the position of the parallel ruler as described above.

  In this respect, according to the ruler fixing portion 80 according to the present embodiment exemplified above, the pressing member 87 made of resin and sufficiently thicker than the fixing screw shaft 85 is pressed, so that an indentation or the like is applied to the connecting bar 81b (82b). No damage. In addition, the pressing member 87 is supported via a ball bearing 86 so as to be rotatable relative to the fixed screw shaft 85. For this reason, the propulsive force (tightening force) in the rotational direction of the fixed screw shaft 85 is not transmitted to the pressing member 87, and as a result, the pressing member 87 is displaced in the surface direction as the fixing screw shaft 85 is tightened. do not do. For this reason, only the pressing force in the thickness direction is applied to the upper surface of the connecting bar 81b (82b) via the pressing member 87, and no frictional force that causes a positional shift is generated. Fine adjustment of the position of 81b (82b) and the position of the ruler body 81a (82a) can be performed accurately.

  In the above-described configuration, the rubber pin 84 is pressed against the outer ring of the ball bearing 86 to prevent the pressing member 87 from rotating. However, the rubber pin or the engagement pin only enters the cutout portion 87a. The pressing member 87 may be prevented from rotating.

  13 and 14, a cutting machine 1 in which the cutting machine body 20 is additionally equipped with a hanging hook 90 for hanging the cutting machine 1 on a stepladder, an edge of a work table or the like (hanging part T). It is shown. The hanging hook 90 includes a hook body 91 in which a steel wire having a thickness of about 5 mm is bent at three locations, and a support portion 92 that supports the hook body 91 on the back side of the blade cover 21. The hook body 91 includes a base shaft portion 91a, a first bending shaft portion 91b bent at an acute angle laterally from the upper end of the base shaft portion 91a, and a first bending shaft portion 91b bent downward by approximately 90 ° from the tip end of the first bending shaft portion 91b. It has a second bending shaft portion 91c and a third bending shaft portion 91d bent upward in a U shape from the lower part of the second bending shaft portion 91c. The third bending shaft portion 91d extends longer upward than the second bending shaft portion 91c.

  The support portion 92 has a cylindrical shape that allows the base shaft portion 91a of the hook body 91 to be inserted into the inner peripheral side. The support part 92 is attached to the front part near the back side of the blade cover 21. The support portion 92 is fixed so that its axis is inclined obliquely rearward with respect to the base 10. The lower portion of the base shaft portion 91a is inserted into the inner peripheral side of the support portion 92, and the hook body 91 is supported so as to be rotatable about the axis of the base shaft portion 91a. The base shaft portion 91a is supported by the support portion 92 in a state in which it cannot be displaced in the axial direction. The suspension hook 90 can be taken out to the use position where the second and third bending shaft portions 91c and 91d are displaced forward as shown in FIG. 13 by rotating around the axis of the base shaft portion 91a. The second and third bending shaft portions 91c and 91d can be stored in the storage position displaced to the handle portion 50 side.

  As shown in FIGS. 13 and 14, the suspension hook 90 is taken out to the use position, and the end of the suspension portion T such as a work table is inserted between the base portion 91a and the second and third base portions 91c and 91d. By doing so, the cutting machine 1 can be suspended. The hanging hook 90 of the present embodiment has a function (power cord hooking portion) for hooking and storing the power cord 55 in addition to the function of hanging the cutting machine 1. As shown in FIGS. 13 and 14, the power cord 55 when not in use can be hooked on the third bending shaft portion 91d in a coiled state.

  The bending direction of the third bending shaft portion 91d that functions as the power cord hooking portion is set so that the tip end side is upward when the cutting machine 1 is suspended by the suspension hook 90. As shown in FIG. 13, when the third bending shaft portion 91d is in a suspended state with its distal end positioned upward with respect to the direction of gravity, the power cord hooked on the third bending shaft portion 91d 55 is accommodated by moving to the bottom side of the U-shaped bending portion formed by the second bending shaft portion 91c and the third bending shaft portion 91d so as not to be detached from the third bending shaft portion 91d.

  By hooking the power cord 55 when not in use to the third bending shaft portion 91d of the hanging hook 90, the power cord 55 can be stored neatly and neatly in a wound state. In this regard, for example, as disclosed in Japanese Patent Application Laid-Open No. 2006-116815, if the power cord is wound around the main body of the cutting machine when it is not in use, it is troublesome to pull out at the next work and the work cannot be started quickly. According to the illustrated power cord hooking portion (third bending shaft portion 91d), the power cord 55 can be quickly and easily pulled out and connected to a power outlet at the stage of starting the next work. It can be activated quickly.

  FIG. 15 shows the cutting machine 1 devised to improve the slidability of the base 10 with respect to the cutting material W. The cutting machine 1 shown in FIG. 15 is characterized in that the sliding plate 100 is detachably attached to the lower surface of the base 10 (workpiece contact surface 10a). Since the configuration is the same, the same reference numerals are given and the description thereof is omitted. 16 shows the upper surface side of the sliding plate 100, and FIG. 17 shows the lower surface side. The sliding plate 100 is provided with an insertion window portion 100 a in accordance with the window portion 10 b of the base 10. The sliding plate 100 is attached to the base 10 by being screwed to the base 10 in a state where the upper surface side is superimposed on the lower surface of the base 10. Screwing is performed by inserting fixing screws (not shown) from the lower surface side into the four screw holes 100b. The sliding plate 100 can be removed from the lower surface of the base 10 by removing the four screws.

  The sliding plate 100 has a configuration in which four sheet materials 102 to 105 are attached to the lower surface of the mounting plate 101. For the four sheet materials 102 to 105, sheet materials having a small friction coefficient made of ultrahigh molecular weight polyethylene are used. As shown in FIG. 17, a sheet material 105 is attached along the front-rear direction along the lower right edge side of the base 10, and a sheet material 102 is attached along the front-rear direction along the left edge side. Further, a sheet material 103 is attached to the front side of the insertion window portion 100a, and a sheet material 104 is attached to the rear side.

  A concave portion 100 c for allowing the guide portion 10 c of the base 10 to escape is provided at the front portion of the sliding plate 100. The sheet material 103 is affixed in a range from the inside of the concave portion 100c to the front portion of the insertion window portion 100a. The sheet material 104 is affixed in a range from the rear portion of the insertion window portion 100a to the rear portion of the mounting plate 101. Each sheet material 102-105 is affixed on the attachment board 101 by adhesion | attachment, respectively.

  As shown in FIG. 16, the front edges of the four sheet materials 102 to 105 in the cutting progress direction are folded back to the upper surface side of the mounting plate 101. In FIG. 16, reference numerals 102 a, 103 a, 104 a, and 105 a are assigned to the folded portions of the sheet materials 102 to 105, respectively. The sheet material 103 is folded back from the inside of the recess 100c to the upper surface side. Each folded portion 102 a, 103 a, 104 a, 105 a is sandwiched between the lower surface of the base 10 when the sliding plate 100 is attached to the lower surface of the base 10. In this way, the front side in the cutting progress direction of each of the sheet materials 102 to 105 is folded back to the upper surface side, and the folded portions 102a, 103a, 104a, and 105a are sandwiched between the lower surface of the base 10 and the cutting machine. The sheet materials 102 to 105 are not easily peeled off from the mounting plate 101 by an operation in which the lower surface of the base 10 (in this case, the lower surface of the sliding plate 100) is slidably brought into contact with the upper surface of the cutting material W. It has become.

  As shown in FIG. 18, the folded portions 102 a to 105 a of the sheet materials 102 to 105 are folded back into the recesses 101 a provided on the upper surface of the mounting plate 101. Therefore, the folded portions 102 a to 105 a are folded back flush with the upper surface of the mounting plate 101. Thereby, the attachment plate 101 is overlapped in a close contact state without generating a gap with the lower surface of the base 10.

  Thus, by attaching the sliding plate 100 to which the sheet materials 102 to 105 having a small frictional resistance are attached along the lower surface of the base 10, the cutting material W can be prevented from being damaged, and the cutting machine 1 Can be moved smoothly to increase cutting efficiency.

  The sliding plate 100 can be removed from the lower surface of the base 10 by removing the four screws. For this reason, when the sheet materials 102 to 105 are peeled off, the work can be resumed in a short time by replacing with another slide plate 100 prepared in advance.

  Further, as illustrated above, by dividing the sheet material into four sheet materials 102 to 105, the upper edge thereof (particularly, the edge of the sheet material 103) corresponds to the concavo-convex shape (concave portion 100c) of the mounting plate 101, and the upper surface It can be folded back beautifully.

  Conventionally, for example, Japanese Patent Laid-Open No. 2006-26886 discloses a technique for directly applying a fluorine coating to the lower surface of a base to improve its slidability, and Japanese Patent Laid-Open No. 2015-136873 discloses a polyethylene sheet on the lower surface of a base. A technique for directly attaching and improving slidability is disclosed. According to these conventional techniques, although the slidability of the base with respect to the cutting material is improved, it is not possible to cope with a case where high slidability is not required. Japanese Patent Application Laid-Open No. 2006-289869 discloses a technique for improving the slidability by detachably attaching a fluorine-coated plate to the lower surface of the base. Has a problem that the slidability is lowered. Japanese Patent Application Laid-Open No. 2001-315075 discloses a technique for improving the slidability by attaching a plate made of ultrahigh molecular weight polyethylene to the lower surface of the base. There is a problem that the maintenance cost increases.

  In this regard, according to the sliding plate 100 exemplified above, the mounting plate 101 on which the sheet materials 102 to 105 made of ultrahigh molecular weight polyethylene and having a small friction coefficient are attached is attached to the lower surface (material contact portion 10a) of the base 10. Since it is the structure which carries out screwing, when the high slidability of the base 10 is not required, it can remove easily. Further, since the sheet materials 102 to 105 made of ultra-high molecular weight polyethylene instead of fluorine coating are pasted as in the conventional case, even if the cutting material W is wet due to water wet or the like, it is highly slippery. Mobility can be secured. Further, since the sheet materials 102 to 105 made of ultra high molecular weight polyethylene are attached to the mounting plate 101, when the sheet materials 102 to 105 are damaged such as peeling or scratching, the sheet It is sufficient to replace only the materials 102 to 105, and in this respect, the maintenance cost can be reduced as compared with the case where a plate made of a conventional high molecular weight polyethylene is replaced.

  According to the portable processing machine 1 of the present embodiment configured as described above, the sliding plate 100 is attached to the lower surface of the base 10 to ensure high slidability with respect to the workpiece W of the portable processing machine 1. can do. The sliding plate 100 has a configuration in which a plurality of sheet materials 102 to 105 are attached to the lower surface of a mounting plate 101 that can be attached to and detached from the lower surface of the base 10. The sliding plate 100 can be removed from the lower surface of the base 10 when not needed, and in this respect, the usability of the portable processing machine 1 is not damaged.

  Further, since the sheet materials 102 to 105 are made of ultrahigh molecular weight polyethylene, high slidability is exhibited even with respect to the workpiece W having a high water content. Further, when the sheet materials 102 to 105 are damaged such as scratches, it is sufficient to replace only the damaged sheet material, and therefore maintenance costs can be reduced.

  Further, since the front end side of each sheet material 102 to 105 is folded back to the upper surface side and is sandwiched between the lower surface of the base 10, the sheet material 102 to 105 is prevented from being peeled off and highly slid. Sex can be maintained over a long period of time. In addition, since the folded portions 102a to 105a are disposed in the recesses 101a provided on the upper surface of the mounting plate 101, no gap is generated between the base 10 and the mounting plate 101 due to the pinching.

  Further, a concave portion 100c is provided at the end of the mounting plate 101 in accordance with the concave and convex shape of the base 10, but the sheet material 103 is folded back to the upper surface side at the bottom of the concave portion 100c and does not block the concave portion 100c. Affixed to the state.

  Various modifications can be made to the embodiment described above. For example, the sliding plate 100 attached to the lower surface of the base 20 is exemplified by the configuration in which a plurality of sheet materials 102 to 105 are attached to the attachment plate 101. Good.

  In addition, the configuration in which the end portion on the front side in the cutting direction of each sheet material 102 to 105 is folded back to the upper surface side of the mounting plate 101 is illustrated, but such folding or folding to the end surface side of the mounting plate 101 may be omitted. .

  Furthermore, although the sliding plate 100 screwed to the base 20 at four positions is illustrated, the sliding plate 100 is detachably attached to the base by hooking a claw on the end of the base 20 or elastically engaging a clip. It may be a moving plate.

  Moreover, although the cutting machine 1 called what is called a portable Marunoko was illustrated as a portable processing machine, the portable machine of other forms, such as a jig for sawing by reciprocating up and down a router for grooving, and a long blade, is carried out. The sliding plate 100 exemplified in the base of the processing machine can be applied.

1. Cutting machine (portable processing machine)
W ... Cutting material 10 ... Base 10a ... Workpiece contact surface, 10b ... Window part, 10c, 10d ... Guide part 10e ... Ruler holding groove, 10f ... Fixing base part, 10ff ... Fixing screw hole 11 ... Front support part 12 ... Rear support part 13 ... Left and right tilting spindle (front side)
14 ... Tilt plate (front side)
15 ... Vertical tilting support shaft 16 ... Thumb screw (front side)
17 ... Left and right tilting spindle (rear side)
18 ... Tilt plate (rear side)
19 ... Pinch screw (rear side)
DESCRIPTION OF SYMBOLS 20 ... Cutting machine main body 21 ... Cutting tool cover, 21a ... Arrow 22 which shows the rotation direction of the cutting tool 22 ... Cutting tool 23 ... Movable cover, 23a ... Opening / closing lever 24 ... Lighting tool 30 ... Electric motor 31 ... Motor case 32 ... Stator 33 ... Rotor 34 ... sensor substrate 35 ... motor shaft, 35a, 35b ... bearing, 35c ... drive gear portion J ... motor axis 36 ... cooling fan 36a ... baffle plate 37 ... intake window 38 ... ventilation opening 39 ... ventilation opening 40 ... deceleration Gear part 41 ... Spindle 42 ... Blade fixing screw 43 ... Gear case 44, 45 ... Bearing 46 ... First driven gear 47 ... Intermediate shaft, 47a, 47b ... Bearing 48 ... Second driven gear 49 ... Third driven gear 50 ... Handle part 51 ... Standing portion 52 ... Grip portion 53 ... Power source operation member, 53a ... Support shaft 54 ... Lighting switch 55 ... Power cord, 55a ... Protective tube, 55b ... Fixed 55c ... plug 56 ... power indicator lamp 57 ... lock-on button 58 ... switch body 59 ... handle cover D ... butt face 59L ... left half part 59R ... right half part 59R1 ... first Division part, 59R2 ... 2nd division part, 59R3 ... 3rd division part 60 ... Controller accommodation part 61 ... Controller 64 ... Cord hook part 65 ... Duct 66 ... Capacitor case 67 ... Electrolytic capacitor 68 ... AC power source 69 ... Power outlet 70 ... Cutting depth adjustment mechanism 71 ... Depth guide, 71a ... Guide groove hole 72 ... Fixing lever 73 ... Fixing screw shaft 80 ... Ruler fixing part 81 ... Parallel ruler (short type)
81a ... Ruler body, 81b ... Connecting bar 82 ... Parallel ruler (long type)
82a ... Rule body, 82b ... Connecting bar 84 ... Rubber pin 85 ... Fixing screw shaft 86 ... Ball bearing (friction reduction part)
87 ... Pressing member, 87a ... Notch 88 ... Operating member, 88a ... Retaining ring 89 ... Fixing nut 90 ... Hanging hook 91 ... Hook body 91a ... Base shaft portion, 91b ... First bending shaft portion, 91c ... Second bending Shaft portion 91d ... third bending shaft portion (power cord hooking portion)
92 ... support part T ... hanging part 100 ... sliding plate 100a ... insertion window part, 100b ... screw hole, 100c ... concave part 101 ... mounting plate, 101a ... concave part 102-105 ... sheet material, 102a-105a ... folding part

Claims (8)

A sliding plate that is detachably attached to a workpiece contact surface that is a lower surface of a base of a portable electric processing machine, and is attached with a highly slidable sheet material. The sliding plate according to claim 1, wherein the sheet material is attached to the lower surface of the mounting plate, and an end portion of the sheet material is bent toward the upper surface side. The sliding plate according to claim 2, wherein an end portion of the sheet material is folded back to an upper surface side, and the folded portion is sandwiched between the mounting plate and the base in a state of being attached to the base. Sliding plate. 4. The sliding plate according to claim 3, wherein the folded portion of the sheet material is positioned in a recess provided on an upper surface of the mounting plate. 5. The sliding plate according to claim 2, wherein the sheet material is bent toward an upper surface side in accordance with a concavo-convex shape in a surface direction of an end portion of the mounting plate. . 6. The sliding plate according to claim 5, wherein the sheet material is divided into a plurality of sheets in accordance with the uneven shape of the mounting plate, and an end portion of each sheet material is matched with the uneven shape on the upper surface side. A sliding plate bent to the back. The sliding plate according to any one of claims 1 to 6, wherein the sheet material is made of ultrahigh molecular weight polyethylene. The portable electric processing machine which attached to the base the sliding plate as described in any one of Claims 1-7.

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