JP2022148245A - Table top cutter - Google Patents

Abstract

To solve the problem that a table top cutter, in which bending deformation is suppressed by improving rigidity of a turntable, is conventionally required.SOLUTION: A turntable 4 of a table top cutter 1 includes: a disk-like top plate part 50 on an upper surface of which a material to be cut is placed; and a connection part 51 by which a cutter body is connected at a rear part of the top plate part 50. A rotary shaft part 52 which is extended downward from the center of a lower surface of the top plate part 50 and is rotatably attached to a base, and a vertical wall part 53 which is extended downward from an outer peripheral edge of the top plate part 50 and comprises a lower end sliding against the base, are provided. A pair of projections 54 extended frontward from a front surface of a rear part of the vertical wall part 53 are provided at a lower surface of the top plate part 50. A rear part projection 55 extended in a front-rear direction is provided in either right or left region with respect to the rotary shaft part 52. A front part projection 56 extended further frontward from a front end 55a of the rear part projection 55 and toward a direction away from a blade tool and further extended until reaching a front region in front of the rotary shaft part 52 is provided.SELECTED DRAWING: Figure 9

Description

TECHNICAL FIELD The present invention relates to a desktop cutting machine used for cutting a material to be cut such as wood.

For example, this type of tabletop cutting machine includes a base to be placed on a tabletop or floor, a turntable for placing a material to be cut, and a cutting machine body provided above the turntable and equipped with a cutting tool. have. The turntable is horizontally rotatably supported by the base. The cutting machine main body is supported by the turntable so as to be vertically swingable. The cutting tool is rotated using an electric motor as a drive source, and the cutting machine body is swung downward toward the turntable. This allows the cutting tool to cut into the material to be cut placed on the top plate of the turntable.

When the cutting machine body is swung downward, a support arm that supports the cutting machine body receives an upward pulling force. The support arm is connected to a connection at the rear of the turntable. As a result, the connecting portion and the rear portion of the turntable integral with the connecting portion are stressed so as to bend upward. For example, the top plate of the turntable is subjected to stress that bends and deforms the rear portion upward. When the top plate portion is bent and deformed, the horizontality of the top plate portion is impaired, making it difficult to accurately cut the material placed thereon.

Patent Literatures 1 and 2 describe protrusions (ribs) extending downward from the lower surface of the top plate portion of the turntable. The rib extends linearly forward from the rear portion of the top plate portion. Bending deformation of the top plate portion is suppressed by providing the ribs on the lower surface side of the top plate portion. Further, the rib described in Patent Literature 1 is configured to also serve as the vertical wall portion of the cutting edge in the vicinity of the center of the top plate portion. The cutting edge is recessed downward so that the cutting tool can enter below the upper surface of the top plate portion when the cutting machine body is swung downward. Since the rib also serves as the vertical wall portion of the cutting edge, deformation of the cutting edge is suppressed.

Japanese Patent Application Laid-Open No. 2007-331289 JP 2008-137165 A

In order to make the desktop cutting machine lighter than before, for example, it is conceivable to provide a light turntable. In order to reduce the weight of the turntable, it is necessary to have a highly rigid structure that suppresses bending deformation more than before. Therefore, there is a conventional need for a desktop cutting machine in which bending deformation is suppressed by improving the rigidity of the turntable.

According to one feature of the present disclosure, a desktop cutting machine includes a cutting machine body that rotatably supports a disk-shaped cutting tool in a posture extending in the front-rear direction, and a turntable that supports the cutting machine body so as to be vertically movable. have The turntable is provided with a disk-shaped top plate portion on which a material to be cut is placed, and a connecting portion at the rear portion of the top plate portion to which the cutting machine body is connected. A rotating shaft extending downward from the center of the lower surface of the top plate portion and rotatably attached to the base; and a vertical wall portion extending downward from the outer peripheral edge of the top plate portion and having a lower end that slides on the base. is provided. At least one ridge extending forward from the rear front surface of the vertical wall is provided on the lower surface of the top plate. The ridge has a rear ridge extending in the front-rear direction in either the left or right region with respect to the rotating shaft. The ridge has a front ridge that extends further forward from the front end of the rear ridge and in a direction away from the cutting tool until it reaches a front region ahead of the rotating shaft.

Therefore, the rigidity of the turntable can be increased by the ridges provided on the lower surface of the top plate portion. The ridge has a rear ridge that projects forward from the rear portion of the turntable, and a front ridge that extends further forward from the front end of the rear ridge and in a direction away from the cutting tool. Therefore, the ridge extends along the direction of the bending stress that the turntable receives when the connecting portion is pulled upward. Therefore, bending deformation of the turntable can be efficiently suppressed by the ridges. Moreover, the front protrusion extends to the front region of the top plate on which the workpiece is placed. Therefore, the rigidity of the front region of the top plate portion can be improved. Therefore, the horizontality of the upper surface can be maintained in the front region of the top plate portion. As a result, the material to be cut can be stably placed on the top surface of the top plate.

1 is a perspective view of a desktop cutting machine according to a first embodiment; FIG. 1 is a left side view of the tabletop cutting machine including a longitudinal section of the base and turntable; FIG. It is a left view which shows roughly the bending deformation of a turntable. It is a top view of a desktop cutting machine. It is a bottom view of a desktop cutting machine. FIG. 6 is a sectional view taken along the line VI-VI in FIG. 5 and is a longitudinal sectional view of the base and the turntable; It is the perspective view which looked at the turntable from the upper surface side. It is the perspective view which looked at the turntable from the lower surface side right. It is the perspective view which looked at the turntable from the lower surface side. It is a bottom view of a turntable. FIG. 4 is a bottom view schematically showing the flow of bending stress applied to the turntable in the stress direction; It is a bottom view of the turntable which concerns on 2nd Embodiment. It is a bottom view of the turntable which concerns on 3rd Embodiment. It is a bottom view of the turntable which concerns on 4th Embodiment. It is a bottom view of the turntable which concerns on 5th Embodiment. It is a bottom view of the turntable which concerns on 6th Embodiment.

According to another feature of the disclosure, the front end of the front ridge is connected with the vertical wall. Therefore, the rigidity of the front region of the turntable can be further improved. Therefore, the stability of the material to be cut placed on the upper surface of the front area of the top plate portion can be enhanced.

According to another feature of the present disclosure, the front ridge extends in an arc in a direction away from the cutting tool. Therefore, the arcuate front ridge more closely approximates the flow of bending stresses that the turntable is subjected to in the stress direction. Therefore, the rigidity of the turntable can be improved without significantly changing the total weight of the ridges.

According to another feature of the present disclosure, the front ridge intersects an imaginary plane passing through the center of the pivot and extending in the left-right direction at an angle of 10° to 80°. Therefore, the front protrusion is provided across the rear area of the turntable behind the imaginary plane and the front area of the turntable ahead of the imaginary plane. The direction of the flow in the stress direction has already changed in the direction away from the cutting tool behind the imaginary plane. Therefore, by providing the front protrusion along the flow in the stress direction, it is possible to improve the rigidity of both the rear region and the front region of the turntable.

According to another feature of the present disclosure, the rear ridge extends across the longitudinal wall and the rear end of the rear ridge is connected with the connecting portion. Therefore, the rear projection is connected to the top plate portion, the vertical wall portion, and the connection portion. Therefore, it is possible to improve the rigidity of the top plate portion on which the rear projection is provided by utilizing the rigidity of the vertical wall portion and the connecting portion.

According to another feature of the present disclosure, the connecting portion has a tubular shape extending in the front-rear direction. The rear projection extends along either the left or right side surface of the connecting portion. Therefore, the rear protrusion is connected to the connecting portion along the left and right side surfaces of the connecting portion extending in the front-rear direction. Therefore, the rigidity in the front-rear direction of the rear protrusion can be increased. The rear protrusion is connected to the lower surface of the top plate portion so as to extend in the front-rear direction. Therefore, it is possible to improve the rigidity of the top plate portion to which the rear projection is connected.

According to another feature of the present disclosure, the front ridge extends from the front end of the rear ridge and has a lower vertical height. Therefore, the vertical height of the front protrusion can be changed according to the required rigidity at each position of the turntable. The bending stress that the turntable receives decreases from the rear to the front. Therefore, it is possible to reduce the weight of the turntable while ensuring the necessary rigidity at each position of the turntable.

According to another feature of the present disclosure, the turntable has a second ridge extending rearwardly from the rear surface of the rotating shaft portion and away from the cutting tool on the lower surface of the top plate portion. The second ridge intersects the ridge. Therefore, the second ridge intersects the ridge at a relatively large angle. Therefore, by cooperating the protrusion and the second protrusion, it is possible to increase the rigidity of the rear region of the turntable in a wide range.

According to another feature of the present disclosure, the turntable has a third ridge extending longitudinally in a region closer to the cutting tool than the ridge. Therefore, the rigidity of the center of the turntable can be further increased by the third protrusion. Moreover, the third ridge can be provided along the flow in the stress direction. Therefore, bending deformation of the top plate portion can be further suppressed.

A first embodiment of the present disclosure will be described based on FIGS. In this embodiment, a desktop cutting machine 1 called a so-called slide circular saw is exemplified. As shown in FIG. 1, the tabletop cutting machine 1 has a base 2 to be placed on a tabletop, a floor, or the like, a turntable 4 for placing a material to be cut, and a cutting machine main body 10 . The turntable 4 is positioned above the base 2 and supported by the base 2 . The cutting machine main body 10 is provided above the turntable 4 . A substantially disc-shaped cutting tool 11 called a tipped saw blade is rotatably supported in the cutting machine body 10 . The user is positioned in front of the desktop cutting machine 1 and performs the cutting work. In the following description, regarding members and construction, the extension direction of the side surface of the cutting tool 11 is defined as the front-rear direction, and the front side as viewed from the user is defined as the front side. The up, down, left, and right directions of members and configurations are defined based on the cutting tool 11 seen from the user positioned in front.

As shown in FIGS. 1 and 4, the turntable 4 has a disk-shaped top plate portion 50 in plan view. A table top surface 50a of the top plate portion 50 is provided horizontally. The turntable 4 is rotatable in the horizontal direction around the table rotation support shaft 2a located in the center of the top plate portion 50. As shown in FIG. The rotation structure of the turntable 4 on the table rotation support shaft 2a will be described later in detail.

As shown in FIG. 1, the base 2 has auxiliary tables 3 on both left and right sides of the turntable 4 . The upper surface of the auxiliary table 3 is provided at the same height as the table upper surface 50a. The turntable 4 has a table extension portion 5 extending forward from the front portion of the top plate portion 50 along the side surface of the cutting tool 11 . A cutting edge plate 5a extending in the horizontal direction is provided on the upper surface of the table upper surface 50a and the table extension portion 5. As shown in FIG. At the center of the cutting edge plate 5a, a notch-shaped slot 5b extending in the front-rear direction along the side surface of the cutting tool 11 is provided. An adjust bolt 43 is provided below the table extension 5 to support the table extension 5 from below. The adjustment bolt 43 is supported by the table extension 5 and can be moved up and down by screwing. The adjusting bolt 43 is vertically moved to bring the lower end of the adjusting bolt 43 into contact with the floor surface. This allows the height of the table extension 5 to be adjusted. In addition, rattling in the installation of the table extension portion 5 can be eliminated.

As shown in FIGS. 1 and 2, above the top plate portion 50 and the auxiliary table 3, a wall-shaped positioning fence 6 extending in the horizontal direction and extending upward is provided. The positioning fence 6 is supported on the upper surfaces of the left and right auxiliary tables 3 . The positioning fence 6 has a positioning surface 6a standing vertically on the front surface. The positioning surface 6a is positioned on a vertical plane passing through the table rotation support shaft 2a. The workpiece W placed on the table upper surface 50a is positioned in the front-rear direction by being brought into contact with the positioning surface 6a.

As shown in FIGS. 1 and 4, an arcuate miter scale plate 7 is provided on the front portion of the base 2 in a substantially half-circumferential region. The miter scale plate 7 is provided so as to extend horizontally below the table top surface 50a. The miter scale plate 7 has a plurality of groove-like positioning recesses 7b extending in the radial direction. The positioning recesses 7 b are provided at predetermined angular intervals in the circumferential direction of the miter scale plate 7 . A tip portion of a positioning pin 41a, which will be described later, can enter the positioning recess 7b. The miter scale plate 7 is fixed to the base 2 by fixing screws 7a. The fixing screw 7a is inserted into the elongated hole of the base 2. As shown in FIG. By loosening the fixing screw 7a and moving the miter scale plate 7 in the horizontal direction, the angle between the positioning fence 6 and the cutting tool 11 can be finely adjusted. For example, the angle between the cutting tool 11 and the positioning fence 6 can be precisely adjusted to a right angle with the positioning pin 41a inserted into the positioning recess 7b at the right angle position. This adjustment is mainly made during the production process of the product.

As shown in FIGS. 1 and 2, a body support arm 30 is provided behind the turntable 4 and extends substantially upward. The main body support arm 30 can tilt in the left-right direction around a left-right tilting support shaft 30a extending in the front-rear direction. The lower arm-side connecting portion 30b of the main body support arm 30 is connected to a cylindrical connecting portion 51 provided on the turntable 4 so as to be tiltable in the left-right direction. An elongated slide bar 31 extending parallel to the side surface of the cutting tool 11 and along a horizontal line is provided on the upper portion of the main body support arm 30 . Two slide bars 31 are arranged side by side in the vertical direction. The slide bar 31 supports a slide base 32 that is slidable in the front-rear direction. By sliding the slide base 32 in the front-rear direction, the cutting tool 11 can cut the wide material W to be cut placed on the turntable 4 in the front-rear direction. The cutting machine main body 10 can swing vertically with respect to the slide base 32 about a vertical swing support shaft 10a provided on the slide base 32 and extending in the left-right direction.

As shown in FIG. 2, the cutting tool 11 is rotatably attached to the cutter main body 10 in front of the vertical swing shaft 10a. The cutting tool 11 is integrally attached to an output shaft (not shown) extending in the left-right direction. By swinging the cutting machine main body 10 downward, the cutting tool 11 can be cut into the material W to be cut placed on the top plate portion 50 and the table extension portion 5 .

As shown in FIGS. 1 and 2, the cutter main body 10 has a fixed cover 12 and a movable cover 13 that cover the cutting tool 11 . The fixed cover 12 covers the upper half circumference of the cutting tool 11 . On the left side of the fixed cover 12, a blank arrow 12a indicating the rotation direction of the cutting tool 11 is displayed. The movable cover 13 can cover the lower half circumference of the cutting tool 11 . The movable cover 13 rotates in conjunction with the vertical swing of the cutting machine body 10 to open and close the lower half circumference of the cutting tool 11 . When the cutting machine main body 10 is swung upward, the movable cover 13 rotates in the closing direction (clockwise direction in FIG. 2). Thereby, the lower half circumference range of the cutting tool 11 is covered. When the cutting machine main body 10 is swung downward, the movable cover 13 rotates in the opening direction (counterclockwise direction in FIG. 2). As a result, the lower half circumference of the cutting tool 11 is exposed.

As shown in FIGS. 1 and 4, the cutter body 10 has a motor housing 14 to the right of the fixed cover 12 and the movable cover 13 and to the left of the slide bar 31 . The motor housing 14 accommodates the electric motor 15 . As an example of the electric motor 15, a motor called a DC brushless motor is used. The output of the electric motor 15 is transmitted to the output shaft while being reduced through a reduction gear train located between the electric motor 15 and the cutting tool 11 .

As shown in FIGS. 1 and 4, a rectangular box-shaped controller housing 16 is provided behind the motor housing 14 . Controller housing 16 accommodates controller 17 . The controller 17 has a shallow rectangular parallelepiped case and a control board housed in the case and molded with resin. The controller 17 mainly includes a control circuit for controlling the operation of the electric motor 15, a drive circuit, an auto-stop circuit, and the like.

As shown in FIGS. 1 and 2, a battery mounting portion 18 is provided at the rear portion of the controller housing 16 . The mounting surface of the battery mounting portion 18 faces rearward and extends vertically when the cutting machine main body 10 is positioned at the top dead center. The battery mounting portion 18 can be attached and detached by sliding a substantially rectangular box-shaped battery pack 19 . The battery pack 19 is, for example, a lithium ion battery with an output voltage of 36V. The battery pack 19 can be detached from the battery mounting portion 18 and repeatedly charged using a separately prepared charger. The battery pack 19 can be reused as a power source between other rechargeable power tools such as a screwdriver and an electric drill.

As shown in FIGS. 1 and 2, a handle portion 20 is provided on the upper front portion of the cutting machine body 10 . The handle portion 20 is arranged to the right of the fixed cover 12 and the movable cover 13 . The handle portion 20 has a loop-shaped operating handle 21 extending along the side surface of the cutting tool 11 . A switch lever 22 is provided on the inner peripheral side of the operating handle 21 . The switch lever 22 can be pulled by a user's finger while gripping the operating handle 21 . When the switch lever 22 is pulled, the electric motor 15 is started. A lock-off button 23 is provided on the upper portion of the operating handle 21 . By pressing the lock-off button 23, the switch lever 22 can be pulled. This prevents the electric motor 15 from being started unexpectedly.

As shown in FIG. 1 , the handle portion 20 has a carrying handle 24 behind the operating handle 21 . The carrying handle 24 has one end connected to the left side of the fixed cover 12 and the other end connected to the left side of the controller housing 16 to form a loop shape. The carrying handle 24 is a grip for the user to carry the desktop cutting machine 1 with the cutting machine main body 10 locked at the bottom dead center.

As shown in FIG. 2, a turntable fixing mechanism 35 is provided below the table extension portion 5 . A front portion of the table extension portion 5 is provided with a grip portion 36 having an uneven peripheral edge portion. A user can grip the grip portion 36 to rotate the turntable 4 horizontally with respect to the base 2 . A fixed rod 37 extends from the grip portion 36 toward the inside rearward of the table extension portion 5 . A fixed rod 37 is supported inside the table extension 5 by means of a threaded engagement. By rotating the grip portion 36 around the axis of the fixed rod 37, the fixed rod 37 is displaced in the front-rear direction.

As shown in FIG. 2, the base 2 has a horizontal plate portion 2c extending horizontally. A sandwiching member 38 is provided behind the fixed rod 37 . The sandwiching member 38 is substantially L-shaped when viewed from the left and right sides. The sandwiching member 38 has a rotating shaft 38a extending in the left-right direction near the substantially L-shaped bent portion. The sandwiching member 38 is supported by the table extension 5 so as to be rotatable about a rotating shaft 38a. One end of the sandwiching member 38 is in contact with the rear end of the fixed rod 37, and the other end in the L shape is in contact with the lower surface of the horizontal plate portion 2c.

When the fixed rod 37 is displaced rearward and comes into contact with the sandwiching member 38, the sandwiching member 38 rotates about the rotating shaft 38a. The sandwiching member 38 sandwiches the horizontal plate portion 2 c between itself and the table extension portion 5 . Therefore, the table extension portion 5 and the sandwiching member 38 cannot move in the horizontal direction with respect to the horizontal plate portion 2c, and are locked with respect to the base 2. As shown in FIG. As a result, the turntable 4 can be locked at a predetermined miter angle. Displacing the fixed rod 37 forward reduces (or eliminates) the force pushing the pinching member 38 rearward. Therefore, the sandwiching of the horizontal plate portion 2c by the sandwiching member 38 and the table extension portion 5 is released.

As shown in FIG. 2, a positive lock mechanism 40 is provided below the table extension 5. As shown in FIG. The positive lock mechanism 40 has an unlocking lever 41 (see FIG. 1) and a positioning pin 41a. The lock release lever 41 is provided on the left side of the front portion of the table extension portion 5 . The positioning pin 41a extends toward the inside rearward of the table extension portion 5. As shown in FIG. The positioning pin 41 a is provided at substantially the same height as the miter scale plate 7 . The rear end of the positioning pin 41a can enter the positioning recess 7b by being displaced rearward. The rear end of the positioning pin 41a can be disengaged from the positioning recess 7b by moving forward.

The front portion of the positioning pin 41a shown in FIG. 2 is connected to the unlocking lever 41 (see FIG. 1). The positioning pin 41 a rotates around its axis by operating the lock release lever 41 . An engagement pin extending perpendicularly to the extending direction of the positioning pin 41a is provided substantially in the center of the positioning pin 41a. The engaging pin is in contact with a lead surface integrally provided with the table extension 5 and spirally extending in the front-rear direction. The engagement pin is displaceable in the front-rear direction along the lead surface. The positioning pin 41a is biased rearward by a compression spring 41c.

When the lock release lever 41 is pushed downward, the engagement pin is displaced forward along the lead surface due to the rotation of the positioning pin 41a. The positioning pin 41a is displaced forward against the biasing force of the compression spring 41c. As a result, the rear end of the positioning pin 41a is disengaged from the positioning recess 7b. When the lock release lever 41 is pulled upward, the engaging pin is displaced rearward along the lead surface. The positioning pin 41a is displaced rearward by the biasing force of the compression spring 41c. The rear end of the positioning pin 41 a abuts on the outer peripheral edge of the miter scale plate 7 . When the turntable 4 is rotated horizontally by gripping the grip portion 36 , the positioning pin 41 a enters one of the positioning recesses 7 b provided on the outer peripheral edge of the miter scale plate 7 . Thus, the turntable 4 is positioned at a predetermined miter angle position corresponding to the positioning recess 7b.

As shown in FIG. 2, between the grip portion 36 and the front end of the table extension portion 5, there is provided a cylindrical tilt fixing operation portion 39 having an uneven peripheral edge portion. The tilt fixing operation portion 39 can be rotated around an axis extending in the front-rear direction. The uneven shape of the tilt fixing operation portion 39 is formed in a pattern different from the uneven shape of the grip portion 36 so that the user can easily distinguish between them.

As shown in FIG. 5, a transmission shaft 39a extending in the front-rear direction is provided at the lower portion of the turntable 4. As shown in FIG. A front end of the transmission shaft 39a is connected to the tilt fixing operation portion 39 via a reduction gear portion (not shown). Rotational power of the tilt fixing operation portion 39 is reduced in speed by the reduction gear portion to rotate the transmission shaft 39a around the axis. The rear end of the transmission shaft 39a extends to the arm-side connecting portion 30b. A nut 39b is fastened to the rear end of the transmission shaft 39a to restrict rotation of the transmission shaft 39a with respect to the main body support arm 30 about the axis. When the tilt fixing operation portion 39 is rotated and the transmission shaft 39a is rotated around its axis, the connecting portion 51 and the arm side connecting portion 30b are pressed against each other in the front-rear direction due to the axial force. Therefore, the main body support arm 30 is positioned at a predetermined horizontal tilt angle with respect to the connecting portion 51 . When the transmission shaft 39a is rotated in the opposite direction, the axial force is released. Therefore, the main body support arm 30 can be tilted left and right with respect to the connecting portion 51 around the horizontal tilt support shaft 30a (see FIG. 1).

As shown in FIG. 1, a movable mounting portion 44 is provided on the left side of the table extension portion 5. As shown in FIG. The movable mounting portion 44 has a columnar shape extending linearly in the horizontal direction. The movable mounting portion 44 is horizontally rotatable around a support shaft 44 a provided on the left side of the table extension portion 5 . By rotating the movable mounting portion 44 to the left overhang position, the movable mounting portion 44 can support the workpiece W (see FIG. 2) projecting leftward from the table extension portion 5 from below. can. Further, by rotating the movable mounting portion 44 to the storage position extending in the front-rear direction along the table extension portion 5, the movable mounting portion 44 can be stored compactly. The movable mounting portion 44 is connected to the support shaft 44a so that the top surface is approximately the same height as the table top surface 50a. A leg portion 44 b extending downward is provided at the tip of the movable mounting portion 44 . The length of the leg portion 44b in the vertical direction can be adjusted by a screw operation. Thereby, the height of the upper surface of the movable mounting portion 44 can be adjusted. In addition, it is possible to eliminate looseness in the installation of the movable mounting portion 44 .

As shown in FIG. 7 , the turntable 4 has a cylindrical vertical wall portion 53 extending downward from the outer peripheral edge of the top plate portion 50 . As shown in FIG. 8 , a cylindrical rotation shaft portion 52 extending downward is provided at the center of the lower surface of the top plate portion 50 . The turntable 4 has a plate-like protrusion 54 , a second protrusion 57 and a third protrusion 58 extending downward from the top plate portion 50 . Each of the ridges 54, the second ridges 57, and the third ridges 58 has a substantially constant plate thickness. The top plate portion 50, the table extension portion 5, the connecting portion 51, the rotating shaft portion 52, the vertical wall portion 53, the ridges 54, the second ridges 57 and the third ridges 58 are integrally formed.

As shown in FIG. 6, the rotating shaft portion 52 is attached to the center of the base 2 with a hexagonal bolt 2b. An adhesive is applied to the tip (lower end) of the hexagon bolt 2b to prevent the base 2 from loosening. A urethane ring 2f, a thrust needle bearing 2d and two flat washers 2e are interposed between the head of the hexagon bolt 2b and the rotary shaft portion 52. As shown in FIG. The urethane ring 2f is arranged below the thrust needle bearing 2d with the hexagon bolt 2b passing through it. The thrust needle bearing 2d is vertically sandwiched between two flat washers 2e. The turntable 4 can rotate smoothly with respect to a hexagonal bolt 2b fixed to the base 2 by a thrust needle bearing 2d. The hexagon bolt 2b is fastened to the base 2 so as to slightly crush the urethane ring 2f in the vertical direction. Therefore, the hexagon bolt 2b is fastened with a substantially constant amount of tightening with little variation due to the predetermined elastic force of the urethane ring 2f. Therefore, a substantially constant axial force always acts on the thrust needle bearing 2d, and the rotation of the turntable 4 is stabilized.

As shown in FIG. 6, the lower end 53c of the vertical wall portion 53 contacts the upper surface of the horizontal plate portion 2c provided on the base 2. As shown in FIG. When the turntable 4 rotates horizontally, the lower end 53c slides on the upper surface of the horizontal plate portion 2c.

As shown in FIG. 3, when the cutter main body 10 is swung downward to cut the cutting tool 11 into the material W to be cut, the main body support arm 30 receives an upward pulling force. At this time, the connecting portion 51 connected to the arm-side connecting portion 30b receives bending deformation stress in which the rear side is bent upward. The top plate portion 50 provided integrally with the connecting portion 51 receives bending deformation stress in which the rear side thereof is bent upward.

The flow in the direction of stress was simulated for the turntable 110 in which no protrusions were provided on the lower surface of the top plate portion 50 . FIG. 11 schematically shows the analytical results of the simulation. The black arrows indicate the flow in the stress direction when bending deformation is applied to the connecting portion 51 upward (in the depth direction of the paper in FIG. 11). The direction of the flow in the direction of stress is directed from the connecting portion 51 to the front of the top plate portion 50, and further forward, the direction is gradually changed outward to the left and right. A change in the direction of the stress generally starts at an intermediate position between the rear end and the center of the top plate portion 50 . The flow in the stress direction intersects at an angle with respect to the imaginary plane S passing through the center of the top plate portion 50 and extending in the left-right direction. The magnitude of the stress increases toward the rear end of the top plate portion 50 and decreases toward the front.

As shown in FIG. 10, the ridges 54 are arranged along the flow in the above stress direction. The protrusions 54 are provided on each of the left and right sides of the top plate portion 50 symmetrically with respect to the cutting tool 11 . The ridge 54 includes a rear ridge 55 that intersects the rear front surface of the vertical wall portion 53 and extends linearly in the front-rear direction, and a circular ridge that is connected to the front end 55a of the rear ridge 55 and extends forward. It has an arcuate front ridge 56 .

As shown in FIG. 10 , the rear portion of the rear projection 55 extends further rearward from a vertical wall intersection portion 55 c that intersects the vertical wall portion 53 . The rear projection 55 extends along the left side or the right side of the cylindrical connecting portion 51 so as to approach the center of the connecting portion 51 as it goes rearward on the outside of the vertical wall portion 53 . A rear end 55 b of the rear projection 55 is connected to the left side or right side of the connecting portion 51 . The front end 55a of the rear projection 55 is positioned midway between the rear end of the top plate portion 50 and the virtual plane S in the front-rear direction. The rear projection 55 extends in a direction substantially perpendicular to the imaginary plane S between the front end 55a and the vertical wall intersection portion 55c.

As shown in FIG. 10 , the rear end 56 b of the front projection 56 is connected to the front end 55 a of the rear projection 55 . A front end 56 a of the front protrusion 56 is connected to the front rear surface of the vertical wall portion 53 . The front projection 56 extends forward from a rear end 56b to a front end 56a and extends outward to the left and right away from the cutting tool 11. As shown in FIG. The front protrusion 56 forms a smooth arcuate curve in plan view. The radius of curvature of the front projection 56 is approximately the same as the radius of curvature of the vertical wall portion 53 . The front projection 56 intersects the imaginary plane S orthogonal to the cutting tool 11 at a central intersection 56c located between the rear end 56b and the front end 56a. The front ridge 56 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 60°, at the central intersection 56c.

As shown in FIGS. 8 and 9, the rear projection 55 is provided at substantially the same vertical height between the front end 55a and the vertical wall intersection 55c. The rear projection 55 is provided at approximately the same height from the vertical wall intersection 55c to the rear end 55b, but only near the rear end 55b so that the height decreases toward the rear. formed. The front projection 56 is formed such that its height gradually decreases from the rear end 56b toward the front end 56a. The height of the front ridge 56 at the front end 56a is approximately half the height of the front ridge 56 at the rear end 56b.

As shown in FIGS. 8 to 10, the second ridge 57 linearly extends rearward from the center of the top plate portion 50 and away from the cutting tool 11 . A front end 57 a of the second protrusion 57 is connected to the rear surface of the rotating shaft portion 52 . A rear end 57 b of the second protrusion 57 is connected to the rear front surface of the vertical wall portion 53 . The second protrusion 57 intersects the protrusion 54 at a protrusion intersection portion 57c located between the front end 57a and the rear end 57b. The ridge crossing portion 57c is located near the rear end 56b (front end 55a). The second protrusion 57 extends in a direction at an angle of 30° to 60° with respect to the virtual plane S, for example. The second ridge 57 intersects the ridge 54 at a relatively large angle, for example, close to a right angle.

As shown in FIGS. 8 to 10, the third protrusion 58 linearly extends rearward from the center of the top plate portion 50 . A front end 58 a of the third ridge 58 is connected to the rear surface of the left end or right end of the rotating shaft portion 52 . The front end 58a is located near the front end 57a. A rear end 58 b of the third protrusion 58 is connected to the rear front surface of the vertical wall portion 53 . The third protrusion 58 is arranged in the central region of the top plate portion 50 closer to the cutting tool 11 than the protrusion 54 is. The third ridge 58 extends in a direction substantially orthogonal to the virtual plane S.

As described above, the desktop cutting machine 1 includes a cutting machine main body 10 which rotatably supports a disc-shaped cutting tool 11 in a posture extending in the front-rear direction as shown in FIGS. It has a turntable 4 that is movably supported. The turntable 4 is provided with a disk-shaped top plate portion 50 on which the material W to be cut is placed on the top surface 50a of the table, and a connection portion 51 at the rear portion of the top plate portion 50 to which the cutting machine main body 10 is connected. . A rotating shaft portion 52 that extends downward from the center of the lower surface of the top plate portion 50 and is rotatably attached to the base 2, and a lower end 53c that extends downward from the outer peripheral edge of the top plate portion 50 and slides on the base 2. A vertical wall portion 53 is provided. A pair of protrusions 54 extending forward from the rear front surface of the vertical wall portion 53 is provided on the lower surface of the top plate portion 50 . The ridge 54 has a rear ridge 55 extending in the front-rear direction in either the left or right region with respect to the rotating shaft portion 52 . The ridge 54 has a front ridge 56 that extends further forward from the front end 55a of the rear ridge 55 in a direction away from the cutting tool 11 and extends to a front region ahead of the rotating shaft portion 52. have.

Therefore, the rigidity of the turntable 4 can be increased by the protrusions 54 provided on the lower surface of the top plate portion 50 . The ridges 54 are composed of a rear ridge 55 projecting forward from the rear portion of the turntable 4 and a front ridge extending further forward from the front end 55a of the rear ridge 55 in a direction away from the cutting tool 11. 56. Therefore, the ridge 54 extends along the direction of the bending stress that the turntable 4 receives when the connecting portion 51 is pulled upward. Therefore, bending deformation of the turntable 4 can be efficiently suppressed by the ridges 54 . Moreover, the front projection 56 extends to the front region of the top plate portion 50 on which the material W to be cut is placed. Therefore, the rigidity of the front region of the top plate portion 50 can be improved. Therefore, the horizontality of the upper surface can be maintained in the front region of the top plate portion 50 . As a result, the workpiece W to be cut can be placed on the table upper surface 50a of the top plate portion 50 in a stable posture.

As shown in FIG. 10 , the front end 56 a of the front protrusion 56 is connected to the vertical wall portion 53 . Therefore, the rigidity of the front region of the turntable 4 can be further improved. Therefore, the stability of the workpiece W placed on the table top surface 50a (see FIG. 2) in the front area of the top plate portion 50 can be enhanced.

As shown in FIG. 10 , the front projection 56 extends in an arc shape in a direction away from the cutting tool 11 . Therefore, the arcuate front protrusion 56 is closer to the flow of the bending stress applied to the turntable 4 in the stress direction. Therefore, the rigidity of the turntable 4 can be improved without greatly changing the total weight of the protrusions 54 .

As shown in FIG. 10, the front protrusion 56 intersects an imaginary plane S passing through the center of the rotation shaft 52 and extending in the left-right direction at an angle of 10° to 80°. Therefore, the front protrusion 56 is provided across the rear area of the turntable 4 behind the virtual plane S and the front area of the turntable 4 ahead of the virtual plane S. The direction of the flow in the stress direction has already changed behind the virtual plane S in the direction away from the cutting tool 11 . Therefore, the front projection 56 can improve the rigidity of both the rear region and the front region of the turntable 4 by being provided along the flow in the stress direction.

8 to 10, the rear projection 55 extends to intersect the vertical wall portion 53, and the rear end 55b of the rear projection 55 is connected to the connecting portion 51. As shown in FIGS. Therefore, the rear projection 55 is connected to the top plate portion 50 , the vertical wall portion 53 and the connection portion 51 . Therefore, by utilizing the rigidity of the vertical wall portion 53 and the connecting portion 51, the rigidity of the top plate portion 50 on which the rear projection 55 is provided can be improved.

As shown in FIGS. 8 to 10, the connecting portion 51 has a tubular shape extending in the front-rear direction. The rear protrusion 55 extends along either the left or right side surface of the connecting portion 51 . Therefore, the rear protrusion 55 is connected to the connecting portion 51 along the left and right side surfaces of the connecting portion 51 extending in the front-rear direction. Therefore, the rigidity of the rear projection 55 in the front-rear direction can be increased. The rear protrusion 55 is connected to the lower surface of the top plate portion 50 so as to extend in the front-rear direction. Therefore, the rigidity of the top plate portion 50 to which the rear projection 55 is connected can be improved.

As shown in FIGS. 8 and 9, the front projection 56 extends from the front end of the rear projection 55 and becomes lower in vertical direction. Therefore, the vertical height of the front protrusion 56 can be changed according to the required rigidity at each position of the turntable 4 . The bending stress that the turntable 4 receives decreases from the rear to the front. Therefore, it is possible to reduce the weight of the turntable 4 while securing necessary rigidity at each position of the turntable 4 .

As shown in FIGS. 8 to 10, the turntable 4 has a second ridge 57 extending rearward from the rear surface of the rotating shaft portion 52 on the bottom surface of the top plate portion 50 and away from the cutting tool 11 . A second protrusion 57 intersects the protrusion 54 . Therefore, the second protrusion 57 intersects the protrusion 54 at a relatively large angle. Therefore, by cooperating the protrusion 54 and the second protrusion 57, the rigidity of the rear region of the turntable 4 can be increased in a wide range.

As shown in FIG. 10, the turntable 4 has a third protrusion 58 extending in the front-rear direction in a region closer to the cutting tool 11 than the protrusion 54 is. Therefore, the rigidity of the center of the turntable 4 can be further increased by the third protrusion 58 . Moreover, the third protrusion 58 can be provided along the flow in the stress direction. Therefore, bending deformation of the top plate portion 50 can be further suppressed.

Next, a second embodiment of the present disclosure will be described with reference to FIG. A desktop cutting machine 60 of the second embodiment has a turntable 61 instead of the turntable 4 shown in FIG. A plate-like protrusion 62 extending downward is provided on the lower surface side of the top plate portion 50 of the turntable 61 . The ridge 62 is integrally formed with other components of the turntable 4 such as the top plate portion 50, the connecting portion 51, the vertical wall portion 53, and the like. Although the second ridge 57 and the third ridge 58 are not illustrated in each of the following embodiments, either or both of the second ridge 57 and the third ridge 58 are provided on the lower surface side of the top plate portion 50. It may be provided.

As shown in FIG. 12, the ridges 62 are provided on each of the left and right sides of the top plate portion 50 symmetrically with respect to the cutting tool 11 (see FIG. 10). The protrusion 62 has a rear protrusion 63 that intersects the rear portion of the vertical wall portion 53 and extends linearly in the front-rear direction, and a front end 63a of the rear protrusion 63 that is connected to the rear protrusion 63 and extends forward in an arc shape. has a front ridge 64 of . The rear portion of the rear projection 63 extends further rearward from a vertical wall portion intersection portion 63 c that intersects the vertical wall portion 53 . A rear end 63 b of the rear projection 63 is connected to the left side or right side of the connecting portion 51 . A front end 63a of the rear projection 63 is positioned midway between the rear end of the top plate portion 50 and the virtual plane S in the front-rear direction.

As shown in FIG. 12, the rear end 64b of the front projection 64 is connected to the front end 63a of the rear projection 63. As shown in FIG. A front end 64 a of the front projection 64 is positioned between the front end of the top plate portion 50 and the imaginary plane S. In other words, the front protrusion 64 is not connected to the vertical wall portion 53 . The front projection 64 extends forward from a rear end 64b to a front end 64a, and extends in an arc shape toward the left and right outward away from the cutting tool 11 (see FIG. 10). The front projection 64 intersects the imaginary plane S at a central intersection 64c located midway between the rear end 64b and the front end 64a. The front projection 64 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 60°, at the central intersection 64c.

Next, a third embodiment of the present disclosure will be described with reference to FIG. A desktop cutting machine 70 of the third embodiment has a turntable 71 instead of the turntable 4 shown in FIG. A plate-like protrusion 72 extending downward is provided on the lower surface side of the top plate portion 50 of the turntable 71 . The ridge 72 is formed integrally with other components of the turntable 4 .

As shown in FIG. 13, the ridges 72 are provided on each of the left and right sides of the top plate portion 50 so as to be bilaterally symmetrical with respect to the cutting tool 11 (see FIG. 10). The ridge 72 is connected to a rear ridge 73 that crosses the rear portion of the vertical wall portion 53 and extends linearly in the front-rear direction, and a front end 73a of the rear ridge 73 that extends linearly forward. It has a front ridge 74 that The shape of the rear projection 73 and the positions of the front end 73a, the rear end 73b, and the vertical wall crossing portion 73c are the same as those of the rear projection 63 shown in FIG.

As shown in FIG. 13, the rear end 74b of the front projection 74 is connected to the front end 73a of the rear projection 73. As shown in FIG. A front end 74 a of the front protrusion 74 is connected to the front rear surface of the vertical wall portion 53 . The front projection 74 extends forward from the rear end 74b toward the front end 74a and extends linearly outward to the left and right away from the cutting tool 11 (see FIG. 10). Therefore, the front projection 74 is bent with respect to the rear projection 73 . The front ridge 74 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 60°, at a central intersection 74c located midway between the rear end 74b and the front end 74a. .

Next, a fourth embodiment of the present disclosure will be described with reference to FIG. A desktop cutting machine 80 of the fourth embodiment has a turntable 81 instead of the turntable 4 shown in FIG. A plate-like protrusion 82 extending downward is provided on the lower surface side of the top plate portion 50 of the turntable 81 . The ridge 82 is formed integrally with other components of the turntable 4 .

As shown in FIG. 14, the ridges 82 are provided on each of the left and right sides of the top plate portion 50, symmetrically with respect to the cutting tool 11 (see FIG. 10). The ridge 82 includes a rear ridge 83 that intersects the rear portion of the vertical wall portion 53 and extends linearly in the front-rear direction, and a front portion that is connected to a front end 83a of the rear ridge 83 and extends forward. It has a protrusion 84 . The shape of the rear projection 83 and the positions of the front end 83a, the rear end 83b, and the vertical wall crossing portion 83c are the same as those of the rear projection 63 shown in FIG.

As shown in FIG. 14, the rear end 84b of the front projection 84 is connected to the front end 83a of the rear projection 83. As shown in FIG. A front end 84 a of the front protrusion 84 is connected to the front rear surface of the vertical wall portion 53 . The front protrusion 84 has a linear portion 84e that extends linearly and a curved portion 84d that extends in an arc. The linear portion 84e is provided in a region from the rear end 84b to an intermediate position between the front end of the top plate portion 50 and the imaginary plane S. As shown in FIG. The linear portion 84e extends forward and extends linearly outward to the left and right away from the cutting tool 11 (see FIG. 11). Therefore, the linear portion 84e is provided so as to be bent with respect to the rear projection 83. As shown in FIG. The curved portion 84d is provided in a region from the front end of the straight portion 84e to the front end 84a. The curved portion 84 d extends forward and extends in an arc shape toward the left and right outwards away from the cutting tool 11 . The front projection 84 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 60°, at a central intersecting portion 84c located in the middle of the straight portion 84e.

Next, a fifth embodiment of the present disclosure will be described with reference to FIG. A desktop cutting machine 90 of the fifth embodiment has a turntable 91 instead of the turntable 4 shown in FIG. A plate-like inner protrusion 92 and an outer protrusion 95 extending downward are provided on the lower surface side of the top plate portion 50 of the turntable 91 . The inner ridge 92 and the outer ridge 95 are formed integrally with other components of the turntable 4 .

As shown in FIG. 15, the inner ridges 92 and the outer ridges 95 are provided on each of the left and right sides of the top plate portion 50, symmetrically with respect to the cutting tool 11 (see FIG. 10). The inner protrusion 92 is connected to a rear protrusion 93 that intersects the rear portion of the vertical wall portion 53 and extends linearly in the front-rear direction, and a front end 93a of the rear protrusion 93 that extends forward in an arc shape. It has a front ridge 94 that protrudes. The rear portion of the rear projection 93 extends further rearward from a vertical wall portion intersection portion 93 c that intersects the vertical wall portion 53 . A rear end 93 b of the rear projection 93 is connected to the left side or right side of the connecting portion 51 . A front end 93a of the rear projection 93 is positioned midway between the rear end of the top plate portion 50 and the virtual plane S in the front-rear direction.

As shown in FIG. 15, the rear end 94b of the front projection 94 is connected to the front end 93a of the rear projection 93. As shown in FIG. A front end 94 a of the front protrusion 94 is connected to the front rear surface of the vertical wall portion 53 . The front protrusion 94 extends forward from a rear end 94b to a front end 94a, and extends in an arc shape toward the left and right outward away from the cutting tool 11 (see FIG. 10). The front projection 94 intersects the imaginary plane S at a central intersection 94c located between the rear end 94b and the front end 94a. The front projection 94 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 60°, at the central intersection 94c.

As shown in FIG. 15, the outer ridge 95 is provided at a position farther from the cutting tool 11 (see FIG. 10) than the inner ridge 92 is. The right outer ridge 95 is provided to the right of the right inner ridge 92 . The left outer ridge 95 is provided to the left of the left inner ridge 92 . The outer protrusion 95 is connected to the rear front surface of the vertical wall portion 53 and extends linearly in the front-rear direction. It has an extending front ridge 97 . A front end 96a of the rear projection 96 is arranged at substantially the same front-rear position as the front end 93a. The rear ridge 96 extends substantially parallel to the rear ridge 93 . A rear end 96 b of the rear projection is connected to the rear front surface of the vertical wall portion 53 at a position farther from the cutting tool 11 than the rear projection 93 .

As shown in FIG. 15, the rear end 97b of the front projection 97 is connected to the front end 96a of the rear projection 96. As shown in FIG. A front end 97 a of the front protrusion 97 is connected to the front rear surface of the vertical wall portion 53 . The front protrusion 97 extends forward from a rear end 97b to a front end 97a, and extends in an arc shape toward left and right outward away from the cutting tool 11 (see FIG. 10). The right (left) front projection 97 extends substantially parallel to the right (left) front projection 94 . The front projection 97 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 60°, at a central intersection 97c located between the rear end 97b and the front end 97a. .

Next, a sixth embodiment of the present disclosure will be described with reference to FIG. A desktop cutting machine 100 of the sixth embodiment has a turntable 101 instead of the turntable 4 shown in FIG. A plate-like protrusion 102 extending downward is provided on the lower surface side of the top plate portion 50 of the turntable 101 . The ridge 102 is molded integrally with other components of the turntable 4 .

As shown in FIG. 16, the ridges 102 are provided on each of the left and right sides of the top plate portion 50, symmetrically with respect to the cutting tool 11 (see FIG. 10). The ridge 102 includes a rear ridge 103 that intersects the rear portion of the vertical wall portion 53 and extends linearly in the front-rear direction, and a front end 103a of the rear ridge 103 that is connected to the ridge 103 and extends linearly forward. It has a front ridge 104 that

As shown in FIG. 16 , the rear portion of the rear projection 103 extends further rearward from a vertical wall intersection portion 103 c that intersects the vertical wall portion 53 . A rear end 103 b of the rear projection 103 is connected to the left side or right side of the connecting portion 51 . The front end 103a of the rear projection 103 is positioned midway between the rear end of the top plate portion 50 and the virtual plane S in the front-rear direction. The rear projection 103 linearly extends from the vertical wall intersection 103c toward the front end in a direction approaching the cutting tool 11 (see FIG. 10).

As shown in FIG. 16, the rear end 104b of the front projection 104 is connected to the front end 103a of the rear projection 103. As shown in FIG. A front end 104 a of the front projection 104 is connected to the front rear surface of the vertical wall portion 53 . The front projection 104 extends forward from the rear end 104b toward the front end 104a and extends linearly outward to the left and right away from the cutting tool 11 (see FIG. 10). Therefore, the front protrusion 104 is bent with respect to the rear protrusion 103 . The front ridge 104 intersects the imaginary plane S at an angle of 10° to 80°, preferably 40° to 70°, at a central intersection 104c located midway between the rear end 104b and the front end 104a. .

Various modifications can be added to the desktop cutting machine of each embodiment described above. Instead of the sliding circular saw illustrated in the present disclosure, for example, a desktop circular saw that does not have a sliding function of the cutting machine body may be applied.

A configuration in which the projections are provided symmetrically with respect to the top plate portion 50 is exemplified. Instead of this, the projections may be provided asymmetrically with respect to the top plate portion 50 . For example, only one of the left and right sides of the top plate portion 50 may be provided with a ridge. Alternatively, the shape and the number of protrusions may be different on the left and right sides of the top plate portion 50 . A rear projection connected to the vertical wall portion 53 is illustrated. Instead of this, a rear projection that is not connected to the vertical wall portion 53 may be applied. A rear ridge that extends linearly without a curved portion is illustrated. Alternatively, the rear ridge may include curved or straight curved portions.

An arcuate or linearly curved front ridge is exemplified. Alternatively, it may be curved in another curvilinear shape, such as a parabolic shape. A plate-like protrusion with a substantially constant thickness is illustrated. Instead of this, for example, the thickness of the ridge may be made thicker toward the rear. The second ridge 57 and the third ridge 58 extending from the rear surface of the rotating shaft portion 52 to the rear front surface of the vertical wall portion 53 are illustrated. Alternatively, for example, the second ridge 57 or the third ridge 58 may be configured not to be connected to the vertical wall portion 53 . The shape of the rotating shaft portion 52 is not limited to a cylindrical shape, and may be, for example, a cylindrical shape, a polygonal shape, or the like.

1... Desktop cutting machine (first embodiment)
2 Base 2a Table rotation shaft 2b Hexagonal bolt 2c Horizontal plate 2d Thrust needle bearing 2e Flat washer 2f Urethane ring 3 Auxiliary table 4 Turntable 5 Table extension 5a... Cutting edge plate 5b... Groove hole 6... Positioning fence 6a... Positioning surface 7... Miter scale plate 7a... Fixing screw 7b... Positioning recess 10... Cutting machine body 10a... Vertical swing shaft 11... Cutting tool DESCRIPTION OF SYMBOLS 12... Fixed cover 12a... Arrow 13... Movable cover 14... Motor housing 15... Electric motor 16... Controller housing 17... Controller 18... Battery attachment part 19... Battery pack 20... Handle part 21... Operation handle 22... Switch lever 23... Lock-off button 24 Carrying handle 30 Main body support arm 30a Horizontal tilt support shaft 30b Arm side connecting part 31 Slide bar 32 Slide base 35 Turntable fixing mechanism 36 Grip part 37 Fixing rod 38 Sandwiching member 38a Rotating shaft 39 Tilt fixing operation part 39a Transmission shaft 39b Nut 40 Positive lock mechanism 41 Unlocking lever 41a Positioning pin 41c Compression spring 43 Adjusting bolt 44 Movable mount Placement portion 44a Support shaft 44b Leg portion 50 Top plate portion 50a Table upper surface 51 Connection portion 52 Rotating shaft portion 53 Vertical wall portion 53c Lower end 54 Projection 55 Rear projection 55a... front end 55b... rear end 55c... vertical wall crossing portion 56... front protrusion 56a... front end 56b... rear end 56c... central crossing portion 57... second protrusion 57a... front end 57b... Rear end 57c... Projection crossing portion 58... Third protrusion 58a... Front end 58b... Rear end 60... Desktop cutting machine (second embodiment)
61... turntable 62... ridge 63... rear ridge 63a... front end 63b... rear end 63c... vertical wall section intersection 64... front ridge 64a... front end 64b... rear end 64c... center intersection Part 70... Desktop cutting machine (third embodiment)
71... turntable 72... ridge 73... rear ridge 73a... front end 73b... rear end 73c... vertical wall portion intersection 74... front ridge 74a... front end 74b... rear end 74c... center intersection Part 80... Desktop cutting machine (fourth embodiment)
81... turntable 82... ridge 83... rear ridge, 83a... front end, 83b... rear end, 83c... vertical wall crossing portion 84... front ridge, 84a... front end, 84b... rear end, 84c... center cross Part 84d... Curved part 84e... Straight part 90... Desktop cutting machine (fifth embodiment)
91... Turntable 92... Inner ridge 93... Rear ridge 93a... Front end 93b... Rear end 93c... Vertical wall section intersection 94... Front ridge 94a... Front end 94b... Rear end 94c... Center Intersecting portion 95...Outer protrusion (first protrusion)
96...Rear ridge 96a...Front end 96b...Rear end 97...Front ridge 97a...Front end 97b...Rear end 97c...Center intersection 100...Desk cutting machine (sixth embodiment)
DESCRIPTION OF SYMBOLS 101... Turntable 102... Ridge 103... Rear rib, 103a... Front end, 103b... Rear end, 103c... Vertical wall intersection part 104... Front rib, 104a... Front end, 104b... Rear end, 104c... Center intersection Part 110... Turntable W... Material to be cut S... Virtual plane

Claims (9)

A desktop cutting machine,
a cutting machine main body that rotatably supports a disk-shaped cutting tool in a posture extending in the front-rear direction;
It has a turntable that supports the cutting machine body so as to be movable in the vertical direction, and the turntable is
a disk-shaped top plate on which a material to be cut is placed;
a connecting portion to which the cutting machine body is connected at the rear portion of the top plate;
a rotating shaft portion extending downward from the center of the lower surface of the top plate portion and rotatably attached to the base;
a vertical wall portion extending downward from the outer peripheral edge of the top plate portion and having a lower end that slides on the base;
At least one ridge extending forward from the front surface of the rear portion of the vertical wall section on the lower surface of the top plate section, the ridge comprising:
a rear projection extending in the front-rear direction in either the left or right region with respect to the rotating shaft;
A desktop cutting machine having a front projection extending further forward from the front end of the rear projection and away from the cutting tool until it reaches a front area forward of the rotating shaft. The desktop cutting machine according to claim 1,
The front end of the front ridge is connected to the vertical wall section. The desktop cutting machine according to claim 1 or 2,
The front ridge extends arcuately in a direction away from the cutting tool. The desktop cutting machine according to any one of claims 1 to 3,
The tabletop cutting machine, wherein the front protrusion intersects an imaginary plane passing through the center of the rotating shaft and extending in the left-right direction at an angle of 10° to 80°. The desktop cutting machine according to any one of claims 1 to 4,
The rear projection extends to intersect with the vertical wall portion, and the rear end of the rear projection is connected to the connecting portion. A desktop cutting machine according to claim 5,
The connecting portion has a tubular shape extending in the front-rear direction,
The table cutting machine, wherein the rear projection extends along either the left or right side surface of the connecting portion. The desktop cutting machine according to any one of claims 1 to 6,
The front ridge extends from the front end of the rear ridge and has a lower height in the vertical direction. The desktop cutting machine according to any one of claims 1 to 7,
The turntable has a second ridge extending rearward from the rear surface of the rotating shaft portion and in a direction away from the cutting tool on the lower surface of the top plate portion, and the second ridge is the ridge. A desktop cutting machine that intersects with. The desktop cutting machine according to any one of claims 1 to 7,
The turntable has a third ridge extending in the front-rear direction in a region closer to the cutting tool than the ridge.

Images