JP3725482B2 - How to make a jig for 3D linear cutting - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
    The present invention relates to a method for creating a jig used to fix a workpiece when the workpiece is three-dimensionally cut by a three-dimensional linear cutting device such as a laser processing machine or a plasma gas cutting device.
[0002]
[Prior art]
    In a three-dimensional linear cutting process using a laser beam or plasma gas, a jig for fixing a workpiece is used for processing a three-dimensional workpiece.
[0003]
    Conventionally, this jig has been manually created by a skilled craftsman for each workpiece to be machined, so that it took time and money to create the jig.
[0004]
[Problems to be solved by the invention]
    In this case, the time and cost required for creating the jig are large compared to the time and cost required for cutting the workpiece itself. Such a tendency is particularly noticeable when the number of workpieces to be processed is small, and is an obstacle to realizing the recent trend of high-mix low-volume production.
[0005]
    In view of the above circumstances, an object of the present invention is to provide a three-dimensional linear cutting jig making method that can easily make a three-dimensional cutting jig without requiring a skilled craftsman. Is.
[0006]
[Means for Solving the Problems]
    In the invention of claim 1, when cutting the workpiece (W) by the three-dimensional linear cutting device (1), when creating a jig used to fix the workpiece,
    When the workpiece is supported on the table (3) of the three-dimensional linear cutting apparatus from the drawing data (CD) indicating the three-dimensional shape of the workpiece via the jig, the workpiece is brought into contact with the workpiece. The shape of the workpiece support part (23a) that supports
    Based on the shape of the generated workpiece support portion, a plurality of jig parts (25) having a shape corresponding to the shape of the workpiece support portion are cut out from the material sheet (27),
    A plurality of jig parts cut out are assembled, and a jig assembly (23) having a shape corresponding to the workpiece support portion is assembled by the assembled jig parts.make,
    The jig assembly is created by attaching the jig parts on a jig base that supports the jig assembly with respect to the table.Composed.
[0007]
    The invention of claim 2 is characterized in that the jig part is cut by a three-dimensional linear cutting apparatus (1) for processing the workpiece supported by the jig part.
[0008]
    The invention of claim 3 is characterized in that the plurality of jig parts are cut out from the same material sheet (27).
[0009]
    Claim4In the invention, the plurality of jig parts are provided with identification codes (for example, X14, X15... Y07, Y08, etc. shown in FIG. 5) for identifying the jig parts. When cutting out from the material sheet, the three-dimensional linear cutting apparatus applies the identification code to the corresponding jig part in a state that can be identified with the naked eye.
[0010]
    The invention of claim 5The jig part is formed with first part connecting means (25c), and the jig part is attached to the jig base via the part connecting means.
[0011]
    The invention of claim 6The jig base is formed with second part connecting means (26a), and the jig parts are attached to the jig base via the parts connecting means.
[0012]
    Claim7According to the present invention, a plurality of the jig parts are arranged in parallel to each other at a predetermined interval in a first direction (for example, FIG. 4, X-axis direction), and the second is a direction intersecting the first direction. Are arranged in parallel at a predetermined interval in the direction (for example, FIG. 4, Y-axis direction).
[0013]
    The invention of claim 8 is to create a jig to be used for fixing the workpiece when the workpiece is cut by the three-dimensional linear cutting device.
    From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
    Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
    Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
    The plurality of jig parts are provided with identification codes for identifying the jig parts. When the jig parts are cut out from the material sheet, the jigs corresponding to the identification codes are processed by the three-dimensional linear cutting apparatus. Attached to the parts in a state that can be identified with the naked eye,
    The three-dimensional linear cutting device is a laser processing machine, and the identification code is attached to a jig part by a torch (7d) of the laser processing machine, and is printed by printing the surface of the material sheet.
    The jig assembly is created by attaching the jig parts on a jig base that supports the jig assembly with respect to the table.Composed.
[0014]
    Claim9According to the invention, an identification code indicating a position where the jig parts should be mounted on the jig base can be identified with the naked eye by the three-dimensional linear cutting apparatus when the jig base is cut out from the material sheet. It is configured so as to be attached in a state (for example, X14, X15... Y07, Y08, etc. shown in FIG. 5).
[0015]
    Claim10According to the present invention, the jig assembly is formed with work movement preventing means (23c) for preventing the movement of the work mounted on the jig assembly.
[0016]
    The invention of claim 11When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
    The jig assembly is formed with a workpiece movement preventing means for preventing movement of the workpiece mounted on the jig assembly,
    The workpiece movement preventing means is a workpiece temporary fixing portion (23c) formed on the jig part, and the workpiece temporary fixing portion is simultaneously processed when the jig part is cut out from the material sheet. It is constructed in this way.
[0017]
    Claim12In the invention, the drawing data indicating the three-dimensional shape of the workpiece is constituted by drawing data relating to a drawing showing the machining shape to be cut by the three-dimensional linear cutting apparatus.
[0018]
    Claim13The invention ofWhen cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
A plurality of shapes of the workpiece support portion (23a) are generated, and a plurality of workpieces (W) can be supported on a single jig assembly (23).
[0019]
    Claim14The invention ofWhen cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
    A plurality of types of workpiece support parts (23a) are generated for different workpieces (W), and a plurality of types of workpieces can be supported on a single jig assembly.
[0020]
    Claim15The invention ofWhen cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
    For the same workpiece (W), a plurality of different shapes are generated for the workpiece support portion (23a), and the mounting state of the same workpiece is changed on a single jig assembly (for example, As shown in FIG. 12, the workpiece W can be supported in such a manner that the workpiece W is reversed from the mounting state A1 to the mounting state B1).
[0021]
【The invention's effect】
      According to the first aspect of the present invention, the jig assembly used when machining the workpiece from the drawing data (CD) indicating the three-dimensional shape of the workpiece (W) corresponds to the three-dimensional shape of the workpiece (W). As a result, it is possible to assemble and create a workpiece support portion having the shape as described above, and to easily create a jig for three-dimensional linear cutting without requiring a skilled craftsman.
[0022]
    Further, by attaching the jig part (25) on the jig base (26), a jig assembly can be created with high accuracy.
[0023]
    In the invention of claim 2, since the jig part is cut by the three-dimensional linear cutting apparatus (1) for processing the workpiece supported by the jig part, the three-dimensional linear cutting for processing the jig part is performed. There is no need to prepare a separate processing apparatus, and a jig assembly can be produced economically.
[0024]
    According to the invention of claim 3, by cutting out a plurality of jig parts from the same material sheet (27), it becomes possible to cut out a large number of jig parts efficiently.
[0025]
    Claim4In the invention, each jig part (25) can be easily identified by the identification code. Therefore, when a large number of jig parts are cut out from the material sheet, the jig parts are recognized without confusion. The jig assembly can be assembled efficiently.
[0026]
    Claim5 and 6In this invention, the connection between the jig part and the jig base can be reliably performed by the part connecting means (25c, 26a).
[0027]
    Claim7Since the jig parts are assembled in such a way that the jig parts are arranged in a direction crossing each other, the jig parts that intersect each other are combined so that one supports the other, and a large number of jig parts are complicatedly supported. It can be assembled without providing.
[0028]
    Claim8Since the identification code is attached using the torch (7d) for processing the workpiece (W), the identification code can be attached without using a special device.
[0029]
    Claim9In this invention, the jig parts corresponding to each position of the jig base can be attached without error by the identification code given to the jig base.
[0030]
    Claim10In the invention, when the workpiece (W) is machined by the three-dimensional linear cutting apparatus by the workpiece movement preventing means, the workpiece (W) is slipped off the jig assembly by the movement of the table (3). It is possible to prevent the occurrence of unexpected situations.
[0031]
    Claim11In this invention, since the workpiece temporary fixing portion is processed at the same time when the jig part is cut out from the material sheet, no special labor is required for processing the workpiece temporary fixing portion.
[0032]
    Claim12In this invention, the drawing data relating to the drawing showing the machining shape of the workpiece to be machined can be used as it is for creating a jig, and it is necessary to create a drawing separately in order to create a jig assembly. Absent.
[0033]
    Claim13In the present invention, since a plurality of workpieces (W) can be supported on a single jig assembly (23), a large number of workpieces can be processed at the same time, and the processing efficiency is high. The operating rate of tools can also be increased.
[0034]
    Claim14In the invention, since a plurality of types of workpieces (W) can be supported on a single jig assembly (23), a large number of types of workpieces can be processed at the same time. However, the machining efficiency can be kept high and the operation rate of the jig can be increased.
[0035]
    Claim15According to the present invention, the same workpiece (W) is mounted on a single jig assembly (23) in a form in which the mounting state is changed (for example, as shown in FIG. 12, the workpiece W is mounted from the mounting state A1. In other words, the workpiece can be processed in multiple steps at the same time without changing the jig setup. Accordingly, the processing efficiency and the operation rate of the jig can be increased.
[0036]
    Note that the numbers in parentheses are for the sake of convenience indicating the corresponding elements in the drawings, and therefore the present description is not limited to the descriptions on the drawings.
[0037]
DETAILED DESCRIPTION OF THE INVENTION
    Embodiments of the present invention will be described below with reference to the drawings.
[0038]
    1A is a perspective view showing an example of a three-dimensional laser processing machine, FIG. 1B is a perspective view of a torch portion of the laser processing machine of FIG. 1, and FIG. 2 is a three-dimensional laser processing machine shown in FIG. FIG. 3 is a view showing an example of a workpiece to be cut, FIG. 4 is an overall view showing an example of a jig assembly, and FIG. 5 is a view showing an example of nesting of a jig plate and a base plate. 6 is a partially enlarged view showing the base plate of FIG. 5, FIG. 7 is a partially enlarged view showing the jig plate of FIG. 5, and FIG. 8 is a sectional view showing the positional relationship between the workpiece and the jig plate. FIG. 10 is a perspective view showing an example of the jig plate, FIG. 11 is a perspective view showing another example of the jig assembly, and FIG. It is a perspective view which shows another example of an assembly.
[0039]
    A three-dimensional laser processing machine 1 which is a three-dimensional linear cutting apparatus has a base 2, and a table 3 is provided on the base 2 so as to be movable in the horizontal X-axis direction. A work W to be machined can be set on the table 3 freely. A column 5 is provided on the base 2 so as to straddle the upper side of the table 3, and a saddle 6 that can be moved and driven in a horizontal Y-axis direction (a direction orthogonal to the X-axis direction) is provided on the column 5. It has been.
[0040]
    The saddle 6 is provided with a head unit 7 that can be driven to move in the Z-axis direction which is the vertical direction. As shown in FIG. 1B, the head unit 7 has a first portion 7a on the saddle 6 side and the first portion 7a centered on the axis CT1 of the first portion 7a parallel to the Z axis. A second part 7b provided rotatably in the A-axis direction and a horizontal axis center CT2 of the second part 7b are provided to be rotatable in the B-axis direction with respect to the second part 7b. The third portion 7c and a torch 7d provided on the tip side of the third portion 7c are configured. A laser oscillation means (not shown) is provided so that laser light can be emitted from the torch 7d.
[0041]
    As described above, the laser beam machine 1 drives and positions the table 3 in the X-axis direction, the saddle 6 in the Y-axis direction, the head unit 7 in the Z-axis direction, and the torch 7d in the A-axis and B-axis directions. However, the relative positional relationship between the workpiece W placed on the table 3 and the tip of the torch 7d is three-dimensionally changed, and laser light is emitted from the torch 7d to perform three-dimensional processing on the workpiece W. It has become.
[0042]
    Further, as shown in FIG. 2, the laser processing machine 1 has a main control unit 9, and the main control unit 9 is connected to a processing data creation unit 11, an input / output control unit 12, via a bus line 10. A jig shape generating unit 13, a jig part developing unit 15, a jig nesting unit 16, a machining control unit 17, an input unit 18, a machining data memory 19, and the like are connected. The input / output control unit 12 is connected to the CAD device 21 via a communication network 20 such as a local area network or the Internet.
[0043]
    Since the laser processing machine 1 and the like have the above-described configuration, when the workpiece W having the sheet-like three-dimensional processing shape shown in FIG. 3 is processed using the laser processing machine 1, first, a known CAD device is used. 21 is used to create a machining drawing for the workpiece W, that is, a drawing showing a machining shape to be cut by the laser beam machine 1.
[0044]
    When the machining drawing for the workpiece W is created by the CAD device 21 as CAD data CD as drawing data, the CAD data CD is output to the laser beam machine 1 via the communication network 20. The CAD data CD shows the three-dimensional shape of the workpiece W shown in FIG. 3, and the CAD data CD is immediately stored in the machining data creation unit 11.
[0045]
    The main control unit 9 uses a known processing program PRO for instructing the processing data creation unit 11 to perform a processing operation on the workpiece W by the head unit 7 based on the three-dimensional shape of the workpiece expressed by the CAD data CD. A command is issued to automatically create the method, and the created machining program PRO is stored in the machining data memory 19.
[0046]
    At the same time as the creation of the workpiece W machining program PRO by the machining data creation unit 11, the main control unit 9 sends the workpiece W to a predetermined position on the table 3 based on the CAD data CD. Command to generate jig assembly data to support.
[0047]
    Then, as shown in FIG. 3, the jig shape generation unit 13 virtually expands the work W displayed by the CAD data CD in the memory, and supports the work W on the table 3. The support solid 23b is virtually generated as shown in FIG. Since the specific shape of the work W is clear from the CAD data CD, the generation of the virtual support solid 23b for holding the work W at a predetermined position on the table 3 is performed on the surface of the work W of the virtual support solid 23b. As shown in FIG. 8, the work support surface 23a as a work support portion that comes into contact with and supports the work W is generated so as to have a shape along the surface shape of the work W.
[0048]
    Specifically, as shown in FIG. 4, based on the machining reference height position L1 for instructing the holding position of the workpiece W by the jig assembly 23 shown in FIG. A virtual support solid 23b for supporting the workpiece W on the table 3 is assumed. The solid body 23b has a work support surface 23a formed at the upper part and a lower part placed on the table 3.
[0049]
    The shape of the work support surface 23a can be easily generated by using the CAD data CD of the work W. Thus, when the virtual support solid 23b is generated, the main control unit 9 instructs the jig part expanding unit 15 to expand the jig part 25 based on the generated virtual support solid 23b.
[0050]
    As shown in FIG. 4, the jig part 25 is formed to have the same cross-sectional shape when the virtual support solid 23 b is cut along a plane parallel to the X-axis and Y-axis directions that are orthogonal to each other. That is, as shown in FIG. 4, the virtual support solid 23b is cut by, for example, seven parallel cutting planes (X12, X13,..., X18) set with an interval L2 in the X-axis direction. Cut in the Y-axis direction by four parallel cutting planes (Y07, Y08, Y09, Y10) set at an interval L3. As shown in FIG. 7, each jig part 25 is formed in a shape equal to the cross-section of these cut surfaces. Therefore, among the jig parts 25, a jig that contacts the work W and supports the work W. As shown in FIG. 7, a workpiece support portion 25d having a shape corresponding to the workpiece support surface 23a is formed at a corresponding portion of the part 25. Note that the shape of the work support portion 25d corresponds to the cut portion of the corresponding virtual support solid 23b of each jig part 25, and therefore is not necessarily curved as in the case of the jig part 25 in the Y-axis direction. Of course, the jig part 25 may be formed in a straight line.
[0051]
    As shown in FIG. 9, each jig part 25 is formed with an engagement groove 25a so that the jig parts 25 in the X-axis direction and the Y-axis direction can be engaged with each other so as to intersect each other. The Y-axis jig part 25 has seven engagement grooves 25a that engage with the jig part 25 in the X-axis direction and engage with the jig part 25 at a distance L2 in the lower part of FIG. Are formed upward from the mounting portion 25b. Further, in the X-axis direction jig part 25, four engagement grooves 25a with which the Y-axis direction jig part 25 that engages with the jig part 25 is engaged are spaced at an interval L3. To the lower mounting portion 25b. As shown in FIG. 9, these engaging grooves constitute part of the virtual support solid 23b when the jig parts 25 in the X-axis and Y-axis directions are engaged with each other via the engaging grooves 25a. It forms so that the jig | tool assembly 23 to perform may be comprised.
[0052]
    Further, at least one mounting notch 25c is formed in the lower part of the jig part 25 in the X-axis (or Y-axis) direction, as shown in FIGS. 9 and 10, and the mounting notch 25c will be described later. It is formed so as to be freely engageable with a mounting hole 26 a formed in the jig base 26.
[0053]
    Thus, with respect to the virtual support solid 23b, when the jig part 25 corresponding to the virtual support solid 23b is developed, the main control unit 9 moves the jig part 25 and the jig part 25 to the jig nesting unit 16. Commands the nesting of the jig base 26 to be mounted.
[0054]
    In response to this, the jig nesting unit 16 includes, as shown in FIG. 5, jig parts 25 (total 11 pieces) constituting the jig assembly 23 used for processing the workpiece W and the jig parts 25. Nesting for removing the mounted jig base 26 from the material sheet 27 is performed. At this time, the jig nesting portion 16 distinguishes each jig part 25 in the material sheet 27 by a code indicating a cross-sectional position of each jig part 25 in the virtual support solid 23b, X12, X13,. Part classification codes DN such as Y07, Y08, Y09, and Y10 are given to each jig part 25 subjected to nesting. In addition, when the jig part 25 is cut by the torch 7d, the part classification code DN is generated so that the surface of the material sheet 27 is printed on the surface of the part with a laser beam. To do.
[0055]
    Further, when the jig nesting unit 16 performs nesting of the jig base 26 to which the jig parts 25 are mounted, the jig nesting unit 16 simultaneously mounts each jig part 25 at a predetermined position of the nested jig base 26. The arrangement of the mounting holes 26a for this purpose is also determined by calculation. As shown in FIG. 6, the mounting holes 26 a are the same as the cutting planes (X12, X13,..., X18) in the X-axis direction set when the jig parts development unit 15 generates the jig parts 25. The distance L2 is set at a position corresponding to the mounting notches 25c formed in the jig part 25 in the X-axis direction. In addition, the jig nesting portion 16 simultaneously arranges the attachment holes 26a and applies the part classification code DN of the jig parts 25 in the X-axis direction to be mounted in the attachment holes 26a and the jig parts 25 in the X-axis direction. Similarly, the part classification code DN of the jig part 25 in the Y-axis direction that is mounted in an intersecting manner is also used when the jig base 26 is cut by the torch 7d. A division symbol print command is generated so that the surface of the material sheet 27 is printed on the base surface by a laser beam.
[0056]
    In this way, the jig parts 25 and the jig base 26 on which the jig parts 25 are mounted are nested on the material sheet 27, and when the division symbol print command of the part division code DN for displaying each jig part 25 is generated. The main control unit 9 instructs the processing control unit 17 to start creating the jig assembly 23 for cutting the workpiece W based on the generated data.
[0057]
    In response to this, the processing control unit 17 arranges the material sheet 27 on the table 3 via a handling robot or the like (not shown), and for the arranged material sheet 27, as shown in FIG. The jig parts 25 and the jig base 26 on which the jig parts 25 are mounted are cut by supplying a laser beam from the head unit 7. Since each jig part 25 and the jig base 26 on which these jig parts 25 are mounted are appropriately arranged so as not to cause useless portions in the material sheet 27, the jig parts 25 and the jig base 26 are arranged. Is cut from the material sheet 27 with high material efficiency.
[0058]
    Thus, when the jig part 25 and the jig base 26 are cut out from the material sheet 27, the cut jig base 26 is mounted on the table 3 shown in FIG. Referring to each part classification code DN printed on the jig base 26 and the jig part 25 by the torch 7d, the operator first attaches the corresponding jig part 25 in the X-axis direction to the jig base 26 in the mounting hole. The mounting notches 25c are fitted and engaged with 26a, and are mounted in parallel with each other at an interval L2. Next, the jig part 25 in the Y-axis direction is similarly referred to the part classification code DN, so that the jig part 25 in the X-axis direction already attached on the jig base 26 is engaged. As shown in FIG. 4, the mating grooves 25 a and 25 a are engaged with each other so as to be fitted in parallel with each other at an interval L 3, and the jig assembly 23 is finally assembled on the jig base 26.
[0059]
    As a result, a jig assembly 23 composed of a plurality of jig parts 25 assembled so as to intersect each other at right angles in the X-axis and Y-axis directions is formed on the table 3, and the formed jig assembly On the upper surface of the three-dimensional body 23, a workpiece support surface 23a formed immediately from workpiece support portions 25d formed on each jig part 25 is immediately formed. In this way, by assembling a plurality of jig parts 25 in an intersecting direction, the jig parts 25 are combined such that one of the intersecting jig parts supports the other. As a result, since the assembly itself is three-dimensionally assembled, a large number of jig parts can be assembled without providing complicated support means.
[0060]
    Therefore, the workpiece W to be processed is placed on the workpiece support surface 23a as shown in FIG. As described above, the work support surface 23a is created based on the CAD data CD when the three-dimensional drawing of the work W is drawn. Therefore, as shown in FIG. It is formed in a shape corresponding to the faced shape. Therefore, the workpiece W is mounted on the workpiece support surface 23a in a form that fits perfectly.
[0061]
    In this state, the main control unit 9 instructs the machining control unit 17 to perform machining based on the machining program PRO for the workpiece W, and the machining control unit 17 executes machining on the workpiece W in response thereto. Since the workpiece W is held on the jig assembly 23, accurate processing can be performed.
[0062]
    In the above-described embodiment, the case where the jig assembly 23 is constituted by the jig parts 25 assembled in a mutually orthogonal shape has been described. However, the jig parts 25 are formed so as to intersect in a direction orthogonal to each other. It is not necessary to assemble in the direction of crossing each other other than a right angle. Furthermore, in addition to assembling the jig parts 25 so as to cross each other, various assembly modes of the jig parts 25 can be adopted. In other words, any assembly mode may be used as long as the workpiece support portion 23a along the surface shape of the supported portion of the workpiece W to be processed can be formed by the assembly of the plurality of jig parts 25.
[0063]
    Moreover, although the above-mentioned Example described the case where the jig | tool part 25 was processed with 3D linear cutting processing apparatuses, such as the 3D laser processing machine 1 which processes the workpiece | work W, the process of the jig | tool part 25 is as follows. Of course, it is also possible to use a three-dimensional linear cutting apparatus different from the three-dimensional linear cutting apparatus that processes the workpiece W.
[0064]
    In addition to the three-dimensional laser processing machine 1, a three-dimensional linear cutting apparatus that processes the jig part 25 can use a plasma gas processing machine or other appropriate linear cutting apparatus.
[0065]
    Further, the jig base 26 that supports the jig assembly 23 is not necessarily formed together with the jig parts 25 that support the workpieces W, and a prepared jig base is shared by the jig assemblies. Of course, it can also be used as a base for the above.
[0066]
    Further, a temporary fixing device for a workpiece made of bolts and nuts, a notch for preventing movement, or the like so that the workpiece W mounted on the workpiece support 23a is not displaced at an appropriate position of the jig assembly 23 during processing. A workpiece movement preventing means such as the workpiece temporary fixing portion 23c (see FIG. 8) may be provided. When the workpiece temporary fixing portion 23c is formed on the jig part 25, it is easier and more convenient than retrofitting the workpiece temporary fixing portion 23c if the jig part 25 is processed simultaneously with the cutting process.
[0067]
    Various types of work movement prevention means other than the one shown in FIG. 8 are conceivable. For example, as shown in FIG. 11, one end is engaged with a hole 25e formed in the jig part 25. It is also possible to use a spring 23d and provide a clip 23g for clamping the workpiece at the other end of the spring 23d. In this case, the workpiece W mounted on the workpiece support surface 23a composed of the workpiece support portion 25d of each jig part 25 is clamped by four clips 23g arranged at a pitch of approximately 90 °, and the workpiece W is processed. It can be configured not to move inadvertently.
[0068]
    Moreover, although the above-mentioned Example demonstrated the sheet | seat-like thing as the workpiece | work W, if the shape of the workpiece | work W is not only a sheet-like thing but a workpiece | work which can be processed with a three-dimensional linear cutting processing apparatus, Any shape may be used.
[0069]
    Further, in the case of a workpiece W having a complicated shape as shown in FIG. 12, the workpiece is processed in a plurality of steps while changing the mounting position on the table from, for example, the mounting state A1 to the mounting state B1 in the figure. Needs may arise. In such a case, from the drawing data CD indicating the three-dimensional shape of the workpiece W, the workpiece support surface 23a that is a workpiece support portion that should support the workpiece W in the mounting state A1 and the workpiece W in the mounting state B1 should be supported. Each jig part 25 is formed so that the workpiece support surface 23a is formed on the same jig assembly 23 (if necessary, more workpiece support surfaces 23a). It is also possible to configure such that a plurality of processes are completed by simply moving the workpiece W on the jig assembly 23 without exchanging the solid 23.
[0070]
    Further, a plurality of workpiece support surfaces 23a for a single type of workpiece W are formed on the same jig assembly 23, and a plurality of workpieces W are mounted on the jig assembly 23 at once. A large number of pieces can be processed.
[0071]
    Note that the plurality of types of workpiece support surfaces 23a that can be formed on the jig assembly 23 are not limited to the workpiece support surfaces 23a for a plurality of steps of the same type of workpiece W, but different types of workpieces W. Of course, it is also possible to form the work support surfaces 23 a for supporting them on the same jig assembly 23.
[Brief description of the drawings]
1A is a perspective view showing an example of a three-dimensional laser beam machine, and FIG. 1B is a perspective view of a torch portion of the laser beam machine shown in FIG.
FIG. 2 is a control block diagram of the three-dimensional laser beam machine shown in FIG.
FIG. 3 is a view showing an example of a workpiece to be cut.
FIG. 4 is an overall view showing an example of a jig assembly.
FIG. 5 is a diagram showing an example of nesting of a jig plate and a base plate.
6 is a partially enlarged view showing the base plate of FIG. 5;
7 is a partially enlarged view showing the jig plate of FIG. 5. FIG.
FIG. 8 is a cross-sectional view showing a positional relationship between a workpiece and a jig plate.
FIG. 9 is a perspective view showing a method for assembling a jig plate.
FIG. 10 is a perspective view showing an example of a jig plate.
FIG. 11 is a perspective view showing another example of a jig assembly.
FIG. 12 is a perspective view showing still another example of the jig assembly.
[Explanation of symbols]
    1 …… 3D linear cutting machine (laser machine)
    3 …… Table
    7d …… Torch
    23 …… Jig assembly
    23a: Work support area (work support surface)
    23c …… Workpiece temporary fixing part
    25 …… Jig parts
    25c …… Parts connection means (mounting notch)
    26 …… Jig base
    26a …… Parts connection means (mounting holes)
    27 …… Material sheet
    CD …… Drawing data (CAD data)
    W …… Work

Claims (15)

When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts ,
The jig assembly is created by attaching the jig parts on a jig base that supports the jig assembly with respect to the table.
3D linear cutting jig creation method.     The jig creation for a three-dimensional linear cutting process according to claim 1, wherein the jig part is cut by a three-dimensional linear cutting apparatus for processing the workpiece supported by the jig part. Method.     The three-dimensional linear cutting jig making method according to claim 1, wherein the plurality of jig parts are cut from the same material sheet.     The plurality of jig parts are provided with identification codes for identifying the jig parts. When the jig parts are cut out from the material sheet, the jigs corresponding to the identification codes are processed by the three-dimensional linear cutting apparatus. The method for creating a jig for three-dimensional linear cutting according to claim 1, wherein the jig part is attached in a state that can be identified with the naked eye. Wherein the jig parts, the first part connecting means is formed, through the part connection means, characterized in that attaching the jig part to the jig base, trilinear of claim 1, wherein Cutting jig creation method. Wherein the jig base, a second part connecting means is formed, through the part connection means, characterized in that attaching the jig part to the jig base, trilinear of claim 1, wherein Cutting jig creation method.     A plurality of jig parts are arranged in parallel in the first direction at a predetermined interval, and a plurality of jig parts are arranged in parallel in the second direction, which is a direction intersecting the first direction, at a predetermined interval. The method for creating a jig for three-dimensional linear cutting according to claim 1, wherein the jig is assembled. When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
The plurality of jig parts are provided with identification codes for identifying the jig parts. When the jig parts are cut out from the material sheet, the jigs corresponding to the identification codes are processed by the three-dimensional linear cutting apparatus. Attached to the parts in a state that can be identified with the naked eye,
The three-dimensional linear cutting device is a laser processing machine, and is attached by printing the identification code on a jig part by a torch of the laser processing machine in a form that burns the surface of the material sheet ,
The jig assembly is created by attaching the jig parts on a jig base that supports the jig assembly with respect to the table.
3D linear cutting jig creation method. When the jig base is cut out from the material sheet, an identification code indicating the position where the jig parts are to be mounted is attached to the jig base in a state that can be identified with the naked eye by the three-dimensional linear cutting apparatus. It was constructed as in, three-dimensional linear cutting machining jig creation method of claim 1, wherein.     The jig creation method for a three-dimensional linear cutting process according to claim 1, wherein the jig assembly is formed with a workpiece movement preventing means for preventing movement of the workpiece mounted on the jig assembly. When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
The jig assembly is formed with a workpiece movement preventing means for preventing movement of the workpiece mounted on the jig assembly,
The workpiece movement preventing means is a workpiece temporary fixing portion formed on the jig part,
The workpiece temporary fixing part is a jig creation method for a three-dimensional linear cutting process configured so that the jig part is simultaneously processed when the jig part is cut out from the material sheet.     The drawing data indicating the three-dimensional shape of the workpiece is drawing data relating to a drawing showing a processing shape on which the workpiece is to be cut by the three-dimensional linear cutting processing device. Jig making method. When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
A jig creation method for a three-dimensional linear cutting process , wherein a plurality of shapes of the workpiece support portions are generated, and a plurality of workpieces can be supported on a single jig assembly. When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
A three-dimensional linear cutting jig characterized in that a plurality of types of workpiece support portions are generated for different workpieces, and a plurality of types of workpieces can be supported on a single jig assembly. How to make. When cutting a workpiece with a three-dimensional linear cutting device, when creating a jig used to fix the workpiece,
From the drawing data indicating the three-dimensional shape of the workpiece, when the workpiece is supported on the table of the three-dimensional linear cutting apparatus via the jig, the workpiece support part that contacts the workpiece and supports the workpiece Generates the shape of
Based on the shape of the generated workpiece support portion, from the material sheet, cut out a plurality of jig parts having a shape corresponding to the shape of the workpiece support portion,
Assembling a plurality of the jig parts cut out, and creating a jig assembly having a shape corresponding to the work support site by the assembled jig parts,
Regarding the shape of the workpiece support portion, a plurality of different shapes can be generated for the same workpiece, and the workpiece can be supported on a single jig assembly by changing the mounting state of the same workpiece. A jig creating method for a three-dimensional linear cutting process characterized by the above .

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