KR101254056B1 - Beveling processing device for clamp tracking type - Google Patents

Abstract

(assignment)
SUMMARY OF THE INVENTION The present invention provides a clamp tracking beveling processing device that can be easily mounted on the end of a metal sheet with a small size and light weight.
(Solution)
Positioning the metal plate 3 of the beveling workpiece from the XYZ direction and automatically traveling while controlling the traveling direction, and automatically beveling the beveling predetermined surface to accurately bevel the designated area and beveling end portion 3eb. Is a high precision clamp tracking beveling device that automatically stops, and cooperates with the cutter (4a), the lower wheel (5b) in contact with the lower surface (3c) of the metal plate, and the lower wheel Clamp device 5 having an upper wheel 5a for clamping, and an inclined support plate 6 installed side by side at an angle with the end face 3a being beveled and slidably supported in contact with the end face 3a. And the surface presence detection sensor 8a is provided between the cutter and the rear wheels 5ab and 5bb to automatically stop after the beveling processing of the beveling end portion of the metal sheet is completed.

Description

BEVELING PROCESSING DEVICE FOR CLAMP TRACKING TYPE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a beveling processing apparatus that performs beveling processing of a metal sheet, and in particular, at the end of the metal sheet with a small size and light weight. The mounting area can be easily mounted, and the metal plate of the beveling workpiece is positioned from the XYZ direction to automatically drive while controlling the traveling direction, and the specified area is automatically tracked by the beveling scheduled surface. The present invention relates to a high precision clamp beveling device for beveling aare precisely.

The background art will be described below.

9 is a view showing an embodiment of a conventional beveling processing device. As shown in Fig. 9, the beveling processing device 110 is self-propelled and includes a trolley 114 for traveling on a steel sheet as a workpiece. In the trolley | bogie 114, the several running wheels 116 and 118 (four in the embodiment shown in figure) are provided in the substantially rectangular lower surface. These traveling wheels 116 and 118 form a predetermined angle with the long side of the lower surface of the bogie to face the direction of the arrow A. FIG. In the direction of arrow A, the traveling motor 122 is connected to the front driving wheel 116 via an appropriate transmission mechanism 120, and the rear driving wheel 118 is a chain transmission mechanism ( The chain lock 124 interlocks with the front wheel 116 at a constant speed. As the cutter 126, various types of ones may be used depending on the shape of the beveling to be formed, the thickness of the steel sheet, the material, and the like, but the cutter 126 of the embodiment shown in the drawing is for V-shaped beveling. It is composed of a conical tool post 142 of which the head is cut, and a tip 144 suitably provided on the conical surface. The beveling processing device 110 automatically runs on the steel plate as described above, and moves the cutter 126 by the traveling to beveling. In this beveling process, the roller 152 is in contact with the end face to be processed of the steel sheet, and functions as a guide roller (guide means). Moreover, the cutter 126 cut | disconnects the end surface in the state which the guide roller 152 always contacted the end surface of the steel plate. Therefore, the guide roller 152 and the cutter 126 are disposed at approximately the same height position, and a part of the cutter 126 has a common tangent on the side of the carriage 114 with respect to the circumferential surface of the guide roller 152. It is arrange | positioned so that it may protrude toward the trolley | bogie 114 side rather than). First, the steel sheet to be processed is placed on an appropriate mounting table. Subsequently, the beveling processing device 110 is placed on the steel plate. At this time, the guide roller 152 and the cutter 126 are arrange | positioned to the side of the end surface which should be processed of a steel plate. Then, the nut holding the one L-shaped support plate 146 is loosened to move the support plate 146 to the left and right to adjust the beveling depth. Once the beveling depth is determined, the nut is fastened to secure the support plate 146 to the bracket 130. In this state, an external power source is connected to the beveling processing device 110. After that, the traveling motor 122 and the cutting motor are started by a switch on the controller, and the rotational speed of the traveling motor 122 is selected to a speed suitable for the cutting conditions to start the beveling process (see Patent Document 1). .

Japanese Patent Laid-Open No. 9-314412

In the trolley, however, the trolley has four running wheels on a substantially rectangular bottom surface and a roller which contacts the end surface of the steel sheet and functions as a guide roller (guide means) and travels on a steel sheet as a work piece. In the self-driving beveling processing device, the cutter cuts the end face while the guide roller is always in contact with the end face of the steel sheet. However, in order to bevel the corners of the end face of the steel sheet, it is necessary to attach an extension plate. There was a problem that occurred. In addition, since the end face of the steel sheet was supported by the guide roller, and only the weight was loaded on the steel sheet, there was a problem that the precision of the beveling process did not appear in the Z direction.

The present invention is a beveling processing apparatus which can be easily mounted on the end of a metal sheet material at a small size and light weight, and performs beveling of the metal sheet material, in particular, by positioning the metal sheet material of the beveled workpiece from the XYZ direction. It is an object of the present invention to provide a high precision clamp tracking beveling device for automatically beveling a specified area by automatically driving while controlling a moving direction and automatically tracking a beveling predetermined surface.

The clamping beveling processing device of the clamp invention of the invention according to claim 1 is mounted to travel in contact with the end face and the upper and lower surfaces of the metal sheet. A clamp tracking beveling device for beveling at least one of the end faces and edges of a metal sheet, wherein the beveling device includes a cutter having a blade tip around a rotating body. (cutter), a cutter electric motor for rotating the cutter, a plurality of lower wheels in contact with the lower surface of the metal plate material, and disposed to face the lower wheels, A clamp device having a plurality of upper wheels in contact with an upper surface and cooperating to clamp the metal plate with the lower wheel, the lower wheel and the A motor for a drive wheel for driving any one of the upper wheels, while maintaining a constant positional relationship between the cutter and the end surface and is installed side by side at an angle with respect to the end surface and is slidably supported in contact with the end surface By providing an inclined support plate, at least one of the said end surface and the said edge is beveled, It is characterized by the above-mentioned.

The invention according to claim 2 is a clamp tracking beveling device according to claim 1, wherein the inclined support plate is in contact with either one of the upper side and the lower side of the end face, and is opened at an advancing direction with respect to the end face. By being installed side by side, the positional relationship between the beveling process surface and the cutter is characterized in that it is kept constant.

Invention of Claim 3 is a clamping beveling machine of Claim 2, The said angle is 0.5-5.0 degrees, It is characterized by the above-mentioned. Moreover, the optimal value shall be 0.5-2.5 degrees.

Invention of Claim 4 is a clamp tracking beveling apparatus of Claim 1, Comprising: The beveling residual value is provided in any one of the upper side and the lower side of the said beveled end surface at least 2 mm.

The invention according to claim 5 is a clamp tracking beveling device according to claim 1, comprising: a surface presence sensor for detecting at least one of the upper, lower, and end surfaces of the metal sheet; It is installed between the cutter and the rear wheel, characterized in that the automatic stop at the corner when the surface presence sensor does not detect the surface.

In addition, a guide mechanism for maintaining a constant positional relationship between the cutter and the end surface is provided. The guide mechanism includes a rail and an imitation wheel, and drives the imitation wheel along the groove of the rail so that the monorail (mono) It is an auxiliary installation to hang in the shape of rail), thereby ensuring double safety.

According to the invention of claim 1, a cutter motor for rotating the cutter, a clamp device having a plurality of lower wheels and upper wheels, a wheel driving motor, and an inclined support plate are provided, thereby providing a compact and lightweight end of the metal sheet. It can be easily mounted on the part, and the metal plate of the beveled workpiece is moved from the XYZ direction to automatically run while controlling the traveling direction. A high precision clamp tracking beveling device capable of accurately beveling at least one of the edges can be provided.

According to the invention according to claim 2, the wheel of the beveling processing apparatus is provided by an inclined support plate which is in contact with one of the upper and lower ends of the metal sheet material and is installed side by side at an angle to open in the advancing direction with respect to the end surface. The driving force is directed toward the metal plate, and the component force is the point where the end face or the edge is in contact with the cutter, so that the inclined support plate on the side of the beveling processing device and the direction of the beveling machine is always pressed against the end face. Because of this operation, the positional relationship between the beveling surface and the cutter is kept constant, and the beveling process can be performed with high accuracy.

According to the invention according to claim 3, the angle between the driving direction of the wheel drive and the inclined support plate is 0.5 to 5.0 ° so that the positional relationship between the beveling surface and the cutter is properly maintained so that beveling can be performed with high precision. Can be. 0.5-2.5 degrees are more optimal.

According to the invention according to claim 4, when the beveling residual value is at least 2 mm in either one of the upper side and the lower side of the end face of the beveled metal sheet, the function of the inclined support plate can be exhibited.

According to the invention of claim 5, by providing a surface presence sensor for detecting at least one of the upper surface, the lower surface, and the end surface of the metal sheet material between the cutter and the rear wheel with respect to the traveling direction of the beveling processing device, When the surface presence sensor does not detect the surface, the beveling processing device can be automatically stopped after the beveling of the edge of the metal sheet is completed.

In addition, a double safety can be ensured by providing an auxiliary guide mechanism which is provided with a rail and an imitation wheel, and which drives the imitation wheel along the groove | channel of a rail, and hangs it in a monorail shape.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing the configuration of a clamp tracking beveling apparatus for explaining a first embodiment of the present invention, wherein (a) shows a beveling processing while the beveling processing apparatus automatically runs the end face of the metal sheet. (B) is the figure seen from the arrow F shown by (a), (c) is sectional drawing of the AA line shown by (a), and is sectional drawing of a beveling processing apparatus.
Fig. 2 is a schematic diagram showing the structure of the clamping mechanism and the conveying drive part in the beveling processing apparatus, wherein (a) is a detailed enlarged cross-sectional view of part B shown in Fig. 1 (c), and (b) is the It is the front view of a clamp mechanism and a conveyance drive part as seen from the arrow C shown by a).
Fig. 3 is a schematic view showing an inclined support plate for supporting a flat surface below the end face in the metal plate material, (a) is an enlarged cross-sectional view of part D shown in Fig. 2 (a), and (b) is a It is a top view which shows the shape in which the beveling processing apparatus was arrange | positioned at the beveling start part of a corner, and shows the form which starts automatic driving from the edge of a metal plate material.
4 is a schematic view showing the configuration of the inclined support plate of the beveling processing device, (a) is a plan view showing the shape in which the beveling processing device travels on the end face of the metal sheet, and (b) is a bevel of the edge of the metal sheet. It is a top view which shows the shape which the beveling processing apparatus advanced to the ring end part.
Fig. 5 is a process diagram illustrating a mechanism in which the inclined support plate is automatically driven while beveling by maintaining a constant positional relationship between the cutter and the beveling surface, and (a) is a beveling start portion of the metal plate. (B) shows the state in which the beveling process starts and the inclined support plate rotates toward the end surface of the metal plate material, and (c) shows the inclined support plate is in contact with the metal plate material at an angle. It shows parallel and the beveling process.
6 is a process diagram illustrating a beveling processing device clamping a metal plate to form a beveling process, (a) before the metal plate is clamped, and (b) before the metal plate is clamped to start the beveling process. c) has shown the middle of the beveling process.
Fig. 7 is a schematic view showing the structure of a clamp tracking beveling processing device for explaining the second embodiment of the present invention. (A) shows the beveling processing while the beveling processing device automatically runs the end surface of the metal plate. (B) is sectional drawing of the beveling processing apparatus as sectional drawing of the EE line shown to (a).
Fig. 8 is a plan view showing a beveling processing apparatus with a guide mechanism arranged on the beveling start portion of the edge of the metal sheet, and shows a state in which automatic traveling starts from the edge of the metal sheet.
9 is a view showing an embodiment of a conventional beveling processing device.

First Embodiment

EMBODIMENT OF THE INVENTION Hereinafter, 1st Embodiment of this invention is described in detail, referring drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing the configuration of a clamp tracking beveling device for explaining a first embodiment of the present invention, wherein (a) shows a beveling process while the beveling device automatically runs an end surface of a metal sheet. (B) is the figure seen from the arrow F shown by (a), (c) is sectional drawing of the beveling processing apparatus as sectional drawing of the AA line shown by (a). As shown in Fig. 1 (a), the metal plate 3, which is a welded material and a beveling processing material, is a work table 2 ) Is secured by a fastener 2a using a bolt, nut, or the like. A beveling processing device 1 of clamp clamp type is mounted to run on the end surface 3a of the metal plate 3. In addition, in the clamp tracking beveling device 1, at least a part of the inclined support plate 6, which will be described later, is in contact with the end face 3a of the metal plate 3, and the upper wheel (described later) 5a) and the lower wheel 5b securely clamp the upper surface 3b and the lower surface 3c of the metal plate 3 so that there is no misalignment in the Z direction (up and down direction), thereby beveling the metal plate 3 Do it. In the XYZ direction, in the metal sheet 3, the advancing direction of the beveling processing device 1 is in the X direction, perpendicular to the X direction and the metal sheet 3 in the X direction on the same plane as the X direction. The (up and down) direction is in the Z direction. Moreover, in the end surface 3a of the metal plate 3, the beveling start part 3ea and the beveling process stop the edge of the position where the beveling processing apparatus 1 starts beveling processing. The edge of the position to be called is called the beveling end part 3eb. The beveled surface is also referred to as a beveling surface 3d, and as shown in Fig. 1B, the beveling residual value α of the end surface 3a is lowered (3ab). Equipped with. The beveling residual value α may be provided above 3aa. This beveling residual value (alpha) is equipped with at least 2 mm. Thus, at the time of welding, the beveling residual value (alpha) is provided in any one of the upper side 3aa and the lower side 3ab of the end surface 3a in the beveling process metal plate 3 at least 2 mm. It is sufficient as a protrusion value, and the function of the inclined support plate 6 can be exhibited favorably.

Next, as shown in Fig. 1 (c), the beveling processing device 1 includes a cutter 4a having a blade tip (carbide tip) 4aa around the rotating body, and A plurality of lower wheels contacting the cutter portion 4 including the cutter electric motor 4b for rotating the cutter 4a and the lower surface 3c of the metal plate 3. The driven wheel 5b and the lower wheel 5b face each other and are disposed upwardly, and are in contact with the upper surface 3b of the metal plate 3 so that the metal plate 3 is connected to the lower wheel 5b. A clamp device 5 having a plurality of upper wheels (drive wheels) 5a, which are driving wheels for cooperative clamping, and the upper wheels 5a comprising pulleys or belts or the like. The positional relationship between the motor 5d for driving wheels driven by the rotation transmission means 5c, the end surface 3a of the metal plate 3, and the cutter 4a is fixed. And an inclined support plate 6 which is installed side by side at an angle β with respect to the end face 3a of the beveling of the metal plate 3 and contacts the end face 3a so as to be slidably supported. have. Thereby, the edge (beveling start part) 3ea and the end surface 3a of the metal plate 3 are beveled, leaving the beveling residual value (alpha), and the beveling process surface 3d is formed. In the beveling end portion 3eb, a surface presence detection sensor 8a (described later) detects the state of the beveling processing of the beveling edge 3eb, and the beveling processing device. It is controlled by the control part 10 so that (1) may stop automatically. In addition, although the upper wheel 5a was demonstrated as a driving wheel, you may use the lower wheel 5b as a driving wheel.

According to this, the cutter motor 4b which rotates the cutter 4a, the clamp apparatus 5 provided with the some lower wheel 5b, and the upper wheel 5a, the motor 5d for driving wheels, By providing the inclined support plate 6, it can be easily mounted on the end of the metal plate member at a small size and light weight, and the metal plate member of the beveling workpiece is positioned from the XYZ direction to automatically run while controlling the traveling direction. It is possible to provide a high precision clamp tracking beveling device capable of automatically beveling the end surface of the designated metal sheet and the edge of the metal sheet by automatically following the ring scheduled surface.

Fig. 2 is a schematic view showing the structure of a clamp mechanism and a conveying drive part in a beveling processing apparatus, in which (a) is a detailed enlarged cross-sectional view of part B shown in Fig. 1 (c). (B) is a front view of the clamp mechanism and the conveyance drive section as seen from the arrow C shown in FIG.

As shown in Figs. 2A and 2B, the metal plate 3 is clamped from the top and bottom by the upper wheel 5a and the lower wheel 5b. The clamping force transmits the driving force of the upper wheel 5a, which is the driving wheel, to the metal plate 3, so that the beveling processing device 1 exerts a driving force between the upper surface 3b of the metal plate 3. As a result, the vehicle travels along the upper surface 3b, the end surface 3a, and the lower surface 3c. The lower wheel 5b is a driven wheel and travels on the lower surface 3c of the metal plate 3. The lower wheel 5b is supported to rotate to the support | pillar 5q fixed to the lower board 7c of a frame. In the upper wheel (drive wheel) 5a facing the lower wheel 5b, the rotation output from the driving motor 5d is transmitted by the rotation transmission means 5c, so that the upper surface 3b of the metal plate 3 To drive. A small pulley 5caa is provided in the driving motor 5d, and the small pulley 5caa provided in one of the small pulley 5caa and the front driving wheel 5aa of the driving wheel 5a. ), The belt 5cba is caught. In addition, a front pulley 5aa is provided with a large pulley 5cab, which sequentially transmits a driving force to the driving wheel 5a adjacent to the rear and drives all of the upper wheel 5a. These drive wheels 5a are supported by a shaft and a bearing on a support 5n provided on the upper wheel support plate 5m. Moreover, the combination of a small pulley, a large pulley, and a belt is not limited to these. You can change it accordingly.

The height adjustment bolt holder 5p is fixed to the upper wheel support plate 5m, and the height adjustment bolt 5h is screwed to the height adjustment bolt holder 5p, and the height is adjusted by turning the height adjustment bolt 5h. The adjusting bolt 5h is moved up and down. The height adjustment bolt 5h is inserted into the slideable hole 5ea formed in the middle plate 5e. Then, a spring 5f is inserted into the height adjustment bolt 5h at a position between the intermediate plate 5e and the upper wheel support plate 5m, and the spring 5f is positioned up and down. It is supported to move. The height adjusting bolt 5h is inserted to slide into a hole not shown in the figure formed in the upper plate 7a, and the height adjusting nut 5j is screwed to the end thereof. The height adjustment bolt 5h is fixed by the height adjustment nut 5j and the upper plate 7a. By turning the height adjusting nut 5j, the height adjusting bolt 5h is moved up and down to move the driving wheel 5a up and down. Moreover, 5 g of pressure regulating cams are provided so that the upper surface of the intermediate plate 5e may be moved up and down. At the end of the shaft to which the pressure regulating cam 5g is attached, a pressure regulating handle 5k is installed to interlock with the pressure regulating cam 5g. The intermediate plate 5e is pushed down by turning the pressure regulating handle 5k and rotating the pressure regulating cam 5g. When the intermediate plate 5e is pushed down, the spring 5f contracts and presses the driving wheel 5a to the upper surface 3b of the metal plate 3, so that the driving wheel 5a and the metal plate 3 Generate adequate friction between them. The frictional force generates the propulsion force in the beveling processing device 1, and the beveling of the end surface 3a is performed. Moreover, the cutter 4a is located between the front upper wheel 5aa and the rear upper wheel 5ab, and between the front lower wheel 5ba and the rear lower wheel 5bb, and the center of the cutter part in the figure is shown. The axial position is indicated by a dashed line. It is also possible to generate the clamping force only by the height adjustment bolt 5h without installing the spring 5f or the intermediate plate 5e, so that it may be clamped directly in the body projection state.

FIG. 3 is a schematic view showing an inclined support plate supporting a flat surface below 3ab of the end surface 3a of the metal plate 3, wherein (a) is shown in FIG. It is an enlarged cross-sectional view of the part D, and (b) is a top view which shows the shape in which the beveling processing apparatus was arrange | positioned at the beveling start part of the edge of a metal plate material, and shows the shape which starts automatic driving from the edge of a metal plate material.

As shown in Fig. 3 (a), the inclined support plate 6 of the clamp tracking beveling machine 1 is located below 3ab of the corner 3ea, which is the beveling start of the metal plate 3; In contact. Thereby, the cutter 4a and the metal plate 3 are positioned, and the advancing direction of the beveling processing device 1 is controlled. And the end surface 3a of the metal plate 3 is beveled by the beveling process, and the beveling surface 3d by which the end surface 3a was beveled, and the beveling surface 3d below the beveling surface 3d Beveling residual value (alpha) after a ring process is formed.

As shown in Fig. 3B, the inclined support plate 6 is installed side by side at an angle β so as to contact the edge 3ea and open in the advancing direction with respect to the end surface 3a, and the cutter 4a. ) And the beveling surface 3d are kept constant. In the beginning, the edge 3ea of the metal sheet 3 is the position of the blade tip 4aa of the cutter 4a which is rotating while being in contact with the inclined support plate 6 which is in contact with the angle β. Proceeding to, the end face 3a is beveled. At this time, the driving direction of the drive wheel 5a is parallel to the end face 3a of the metal plate 3. This angle β is an angle set so that the inclined support plate 6 opens in the traveling direction with respect to the end surface 3a of the metal plate 3, and the angle between the drive direction of the drive wheel 5a and the inclined support plate 6 By setting 0.5 to 5.0 °, the positional relationship between the beveling surface 3d and the cutter 4a is kept constant so that beveling can be performed with high accuracy. Moreover, 0.5-2.5 degrees of the angle (beta) are more optimal. In the beveling processing device 1, a surface presence detection sensor 8a is provided between the position of the blade tip 4aa and the rear wheels 5ab and 5bb in the traveling direction. The surface presence detection sensor 8a may be further provided in front, and a plurality of surface presence detection sensors 8a and 8b may be provided respectively, but at least one surface presence detection sensor 8a must be provided at the rear. There is. Thereby, the beveling of the edges 3ea and 3eb can be automatically performed. In addition, the direction of movement of the beveling processing device 1 can be controlled by the inclined support plate 6.

According to this, although the detail is mentioned later in FIG. 5, the driving force f of the drive wheel of the beveling processing apparatus 1 turns to the direction which penetrates into the end surface 3a of the metal plate 3, and the component force Is a direction where the cutter 4a and the end face 3a come into contact with each other, and the pressure supporting plate 6 on the traveling direction side of the beveling processing apparatus 1 is always pressed against the end face 3a. Acts as. For this reason, the positional relationship between the beveling process surface 3d and the cutter 4a is kept constant, and a beveling process can be performed with high precision.

Fig. 4 is a schematic view showing the configuration of the inclined support plate in relation to the beveling processing device, (a) is a plan view showing a state where the beveling processing device travels on the end face of the metal plate material, and (b) is an edge of the metal plate material. It is a top view which shows the shape which the beveling processing apparatus advanced to the beveling end part.

As shown in Fig. 4 (a), the inclined support plate 6 of the clamp tracking type beveling machine 1 is entirely below the end 3ab of the end face 3a of the metal plate material 3. In contact with each other, the cutter 4a and the metal plate 3 are positioned to control the traveling direction of the beveling processing device 1. The end face 3a of the metal plate 3 is beveled by the beveling process below the beveling process surface 3d by which the end surface 3a was beveled, and below 3ab of the beveling process surface 3d. The beveling residual value (alpha) after it is set is continuously formed.

As shown in Fig. 4B, the inclined support plate 6 is in contact with the entire beveling residual value α, including the edge 3eb, which is the beveling end portion of the metal plate 3. The beveling processing device 1 is automatically stopped by detecting that the beveling end portion 3eb of the metal sheet 3 has passed the position of the surface presence detecting sensor 8a. At the same time, the cutter electric motor 4b is stopped and the rotation of the cutter 4a is stopped. Moreover, the surface presence detection sensor 8a which detects the surface of at least one of the upper surface 3b, the lower surface 3c, and the end surface 3a of the metal plate 3 is equipped with the cutter with respect to the advancing direction of the beveling processing apparatus 1. By installing between 4a and the rear wheels 5ab and 5bb, when the surface presence sensor 8a does not detect the surface, beveling of the edge 3eb of the metal sheet 3 is completed. It can be stopped automatically afterwards.

Fig. 5 is a process diagram illustrating a mechanism in which the inclined support plate 6 automatically runs while beveling while maintaining the positional relationship between the cutter 4a and the beveling surface 3d. The support plate 6 is in contact with the metal plate at an angle 3ea at the edge 3ea, which is the beveling start of the metal plate 3, and is in contact with the metal plate. The state which rotates toward the end surface of a board | plate material is shown, (c) has shown the shape in which the inclined support plate is parallel with a metal plate material, and is beveling.

As shown in (a), (b) and (c) of FIG. 5, the component force a and the component force b are generated from the driving force f of the driving wheel 5a, and the component force is caused by the component force a. (a1) is generated, and reaction force a2 is generated by this component force a1, so that the inclined support plate 6 and the end surface 3a are pressed against each other. Thereby, the position of the beveling processing apparatus 1 is stabilized. In addition, the component force b becomes a driving force to drive the beveling processing device 1.

Fig. 6 is a process diagram illustrating a state in which the beveling processing device clamps a metal sheet and beveling, (a) before the metal sheet is clamped, and (b) before the metal sheet is clamped to start beveling. c) indicates that the beveling processing device 1 is moving from the inside to the front side in the drawing during the beveling process.

As shown in Fig. 6A, the cutter 4a and the driving wheel 5a are lowered to the beveling position from above. Next, as shown in Fig. 6B, the cutter 4a further advances from the inner side to the front side in the drawing, and tries to start the beveling process. As shown in Fig. 6C, the beveling process is performed at the beveling angle θ. Moreover, (theta) is 35-45 degrees, but it is not limited to this.

Second Embodiment

EMBODIMENT OF THE INVENTION Hereinafter, 2nd Embodiment of this invention is described in detail, referring drawings.

7 and 8 are schematic views showing the structure of a clamp tracking beveling processing device for explaining the second embodiment of the present invention, and in FIG. 7A, the beveling processing device shows the end face of the metal sheet. Fig. 7B is a sectional view of the EE line shown in (a) and a sectional view of the beveling processing device.

Fig. 8 is a plan view showing the beveling processing device having a guide mechanism arranged on the beveling start portion of the edge of the metal sheet, and showing the state of starting automatic running from the edge of the metal sheet. . The second embodiment differs from the first embodiment in that the guide mechanism is not provided in the first embodiment, but the guide mechanism is applied in the second embodiment. About the same structure as 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

As shown in Figs. 7A and 7B, the guide mechanism is provided in the beveling processing device 1, and the positional relationship between the cutter 4a and the end face 3a is kept constant. A guide mechanism 9 for carrying out is additionally provided. The guide mechanism 9 is for precisely mounting the beveling processing device 1 to the end surface 3a of the metal plate 3, and is made of a metal rail 9a and an imitation wheel 9e. ), And the mimic wheel 9e runs along the groove 9g of the rail 9a, and is suspended by a monorail. Thereby, double safety can be ensured. That is, the rail 9a is being fixed to the appropriate attachment tools 9b and 9b provided in the both ends of the worktable 2. As shown in FIG. And two pillars 9c and 9d extend from the beveling processing apparatus 1. A shaft 9f supported by the support posts 9c and 9d is provided, and the imitation wheel 9e is provided on the shaft 9f so as to rotate by an appropriate fastener. This imitation wheel 9e is inserted to slide in the groove 9g formed in the rail 9a.

As mentioned above, although one preferred embodiment was described, this invention is not limited to the said embodiment, It can change suitably within the range which does not deviate from the summary of this invention. For example, the guide mechanism may be configured to be supported by a simple rope or the like. Moreover, although the rotating direction of a cutter is made counterclockwise, you may set it clockwise. In addition, it is not necessary to install the spring and the intermediate plate.

The present invention can be easily mounted on the end of the metal sheet material in a small size and light weight, and the metal plate material of the beveling workpiece is positioned from the XYZ direction to automatically run while controlling the traveling direction, thereby automatically beveling the beveling scheduled surface. It is applied to beveling processing equipment that requires accurate and low cost beveling of the designated area.

1: Beveling processing device
2: work table
2a: Fixture, metal plate fixture
3: metal plate, welded material, beveling material
3a: end face
3aa: upward
3ab: downward
3b: top view
3c: if
3d: Beveling face
3ea: corner, beveling start
3eb: corner, beveling end
4: Cutter part
4a: cutter
4aa: blade tip, carbide tip
4b: Cutter motor and motor
5: clamp device
5a: Upper wheel, driving wheel
5aa: front driving wheel, front upper wheel, front wheel
5ab: rear wheel, rear top wheel, rear wheel
5b: Lower wheel, driven wheel
5ba: Front driven wheels, front lower wheels, front wheels
5bb: rear driven wheel, rear lower wheel, rear wheel
5c: rotation transmission means, belt, pulley
5caa: sopley
5cab: Daley
5cba: Belt
5cbb: Belt
5cbc: Belt
5cbd: Belt
5d: Motor for driving wheel
5e: middle plate
5ea: hole, sliding hole
5f: spring
5g: Pressure Control Cam
5h: Height adjusting bolt
5j: Height adjusting nut
5k: Pressure regulating handle
5m: Upper wheel support plate
5n: Shoring, driving wheel holder
5p: Height adjustment bolt holder, bolt support part
5q: Shoring, driven wheel stock
6: inclined support plate
7a: top plate
7b: side plate
7c: bottom plate
8, 8a, 8b: Surface presence sensor
9: guide mechanism
9a: rail
9b: mounting fixture, rail fixture
9c: prop
9d: prop
9e: imitation wheel
9f: axis
9g: home
10:

Claims (5)

It is mounted so as to travel in contact with the end surface 3a and the upper and lower surfaces 3b and 3c of the metal plate 3, and the beveling of at least one of the end face and the corner of the metal plate 3 As a clamping beveling processing device (1) of a clamp chamfering type that performs a beveling process,
The beveling processing device,
A cutter 4a having a blade tip 4aa around the rotating body,
A cutter electric motor 4b for rotating the cutter;
A plurality of lower wheels 5b in contact with the lower surface of the metal plate, and a plurality of lower wheels disposed to face the lower wheel and in contact with the upper surface of the metal plate to clamp the metal plate in cooperation with the lower wheel. A clamp device 5 having an upper wheel 5a of
An electric motor for driving wheels 5d for driving any one of the lower wheel and the upper wheel;
While maintaining a constant positional relationship between the cutter and the end surface, and is installed side by side at an angle with respect to the end surface, the inclined support plate (6) which is in contact with the end surface to be slidably supported
The beveling processing device of the clamp follow-up type | mold characterized by beveling at least one of the said end surface and the said edge (3ea, 3eb) by providing.
The method of claim 1,
The inclined support plate is in contact with any one of the upper (3aa) and the lower (3ab) of the end surface, beveling surface by being installed side by side at an angle (β) to open in the direction of travel relative to the end surface, A beveling processing device for clamp tracking type, characterized in that the positional relationship between the machine (3d) and the cutter is kept constant.
The method of claim 2,
Clamp follower beveling processing apparatus, characterized in that the angle is 0.5 to 5.0 °.
The method of claim 1,
The bevelling processing device of the clamping type | mold type | mold characterized in that any one of the upper side and the lower side of the said beveling process is provided with the beveling residual value ((alpha)) at least 2 mm.
The method of claim 1,
A surface presence detection sensor 8 for detecting at least one of the upper, lower and end surfaces of the metal sheet is provided between the cutter and the rear wheels 5ab and 5bb. Clamp follower beveling processing apparatus characterized in that the stop automatically at the corner when the surface presence sensor does not detect the surface.

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