JP4928911B2 - Processing equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a processing apparatus which is capable of using various materials as processing objects, irrespective of reflectivity, and forming a desired image in plentiful expression modes on the surface of the processing object. <P>SOLUTION: The processing apparatus 100 is equipped with a printing carriage 130 which holds an ink head unit 121 for printing the image on the surface of a workpiece WK, an incising carriage 140 which holds an incising stylus 141 for forming a dotlike processing mark on the same surface and a cutting carriage 120 which holds a cutter 121 for cutting the workpiece WK. Based on each processing data for forming the desired image, the processing apparatus 100 prints first the image on the surface of the workpiece WK. Then, it forms the dotlike processing mark on the image and also conducts a cutout of the surface of the workpiece WK. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a processing apparatus for forming a desired image on the surface of the workpiece based on processing data for forming a desired image on the surface of the workpiece.

Conventionally, a plurality of dot-shaped processing marks are formed on the surface of a workpiece that is relatively plastically deformable, such as gold, platinum, brass, aluminum, and stainless steel, and a desired image is obtained by a collection of these processing marks. A processing apparatus for forming on the surface of a workpiece is known (see Patent Document 1 below).
JP 2000-61540 A

  However, in such a processing apparatus, a material having a high light reflectivity (for example, a metal color material such as platinum or brass) is often used as a workpiece in order to form a clear image. For this reason, there has been a problem that the range of selection of materials used as the workpiece is substantially narrow. On the other hand, the inventors of the present invention have a narrow selection range of materials to be used as a workpiece as described above, and that a workpiece to be processed by a processing apparatus is usually composed of one material. Therefore, it was felt that the expression mode of the image formed on the workpiece was monotonous.

  The present invention has been made to address the above problems, and its purpose is to allow various materials to be used as a workpiece regardless of reflectivity, and to form a desired image on the surface of the workpiece by abundant expression modes. It is in providing the processing apparatus which can do.

  In order to achieve the above object, a feature of the present invention is a processing apparatus that forms the desired image on the surface of the workpiece based on processing data for forming the desired image on the surface of the workpiece. The printing processing means for printing an image on the surface of the workpiece, the trace processing means for forming a dotted or linear processing mark on the surface of the workpiece, the printing processing means and the trace processing means, Displacement means for displacing relative to the workpiece is provided.

  According to the feature of the present invention configured as described above, the printing processing means prints images such as characters, figures and colors on the workpiece, and the trace processing means prints dots or lines on the workpiece. A shaped processing mark is formed. Therefore, for example, when a material such as wood or resin having a low reflectance compared to a metal is used as a work piece, after printing a metal color such as gold or silver on the surface of the work piece by a printing process means, a mark processing means Thus, a desired image can be formed by a dotted or linear processing mark. Accordingly, various materials can be used as a workpiece regardless of the reflectance of the material.

  Further, after printing different colors (for example, gold and silver) on the surface of the workpiece by the printing processing means, a desired image can be formed by the dot processing or the linear processing marks by the marking processing means. According to this, a desired image can be formed on the surface of the workpiece by abundant expression modes as compared with the conventional processing apparatus. Further, a plurality of different colors are printed on the surface of the workpiece by the printing processing means (for example, red is printed on the surface and then blue is printed). Form a scar. In this case, the depth at which the processing marks are formed is adjusted so that the color (red) printed on the base appears. According to this, a desired image can be formed on the surface of the workpiece by the color (blue) printed on the surface and the color (blue) printed below the color printed on the surface. That is, a desired image can be expressed by a color other than a metal color such as gold or silver. As a result, a desired image can be formed on the surface of the workpiece by abundant expression modes as compared with the conventional processing apparatus.

  Another feature of the present invention is that the processing apparatus further includes a cutting means for cutting the workpiece, and the displacement means includes the cutting means in addition to the printing means and the trace processing means. Displacement relative to the object. In this case, the processing apparatus first prints an image on the workpiece by the printing processing unit, then forms a processing mark by the marking processing unit, and then performs cutting by the cutting processing unit. Good.

  According to such another feature of the present invention, a cutting means for cutting a workpiece is provided in addition to the printing means and the mark processing means. As a result, in addition to printing an image and forming a processing mark, the workpiece can be cut out and cut, and a desired image can be displayed on the surface of the workpiece by abundant expressions compared to conventional processing apparatuses. Can be formed.

  According to another aspect of the present invention, in the processing apparatus, the displacement unit may be configured such that any one of the printing processing unit, the trace processing unit, and the cutting processing unit is relative to the workpiece. A first connecting means for detachably connecting one of the two processing means other than the one processing means displaced by the driving means and the one processing means. And a second connecting means for detachably connecting the other processing means and the one processing means or the one processing means among the other two processing means. In this case, it is preferable that the first connecting means and the second connecting means connect each processing means in a separable manner using magnetic force.

  According to another aspect of the invention thus configured, the displacing means displaces any one of the printing processing means, the trace processing means, and the cutting processing means relative to the workpiece. Let In this case, one processing means that is directly displaced by the displacing means is provided with first and second connecting means for detachably connecting the other two processing means. For this reason, two processing means other than the processing means directly displaced by the displacement means can be separated from the one processing means when the workpiece is not processed. Thereby, at the time of processing the workpiece, only the one processing means and the processing means for processing the workpiece can be displaced, and the load of the driving means for displacing the processing means can be suppressed. . As a result, it can be expected that the processing accuracy of the workpiece is improved and the life of the driving means is extended.

  Hereinafter, an embodiment of a processing apparatus according to the present invention will be described with reference to the drawings. FIG. 1 shows that a desired image is formed on the surface of the workpiece WK by printing an image on the surface of a single sheet-like workpiece WK, which is a workpiece, and forming and cutting a dotted processing mark. 1 is a perspective view showing the entire processing apparatus 100. FIG. FIG. 2 is a block diagram of a control system that controls the operation of the machining apparatus 100.

  The processing apparatus 100 includes a bed 101 having a flat surface portion arranged in a horizontal state. The bed 101 is a mounting table on which the work WK is mounted on the flat surface portion, and is formed to extend in the horizontal direction in the figure. A cylindrical grid roll 102 is provided at the center of the bed 101 along the flat surface with its upper surface exposed. The grid roll 102 is rotationally driven by an X-axis direction feed motor 103 whose drive is controlled by a controller 116 described later. Further, a long guide rail 104 is provided above the bed 101 along the horizontal direction in the figure, and a pinch roll 105a having a cylindrical portion at a lower portion of the guide rail 104 and facing the grid roll 102. , 105b are provided. The grid roll 102 and the pinch rolls 105a and 105b convey the work WK in the front-rear direction in the figure while sandwiching the work WK. Here, the front-rear direction in the figure for conveying the workpiece WK is the X-axis direction, and the left-right direction in the figure orthogonal to the X-axis direction is the Y-axis direction.

  The guide rail 104 supports the cutting carriage 120, the print carriage 130, and the stamping carriage 140 via the linear motion rail 106 and a linear motion block (not shown). The linear motion rail 106 is a single rail that is fixed to the guide rail 104 along the Y-axis direction. The linear motion block is fixed to the cutting carriage 120, the print carriage 130, and the stamping carriage 140, and is slidably assembled to the linear motion rail 106. Therefore, the cutting carriage 120, the print carriage 130, and the stamping carriage 140 are each guided in the Y-axis direction along the linear motion rail 105, that is, the guide rail 104.

  As shown in FIGS. 3A to 3C, the cutting carriage 120, the print carriage 130, and the stamping carriage 140 are arranged on the right side of the cutting carriage 120 in the drawing, and on the left side of the cutting carriage 120 in the drawing. A stamping carriage 140 is arranged. The cutting carriage 120 is formed in a substantially rectangular parallelepiped shape, and a cutter 121 for cutting the workpiece WK is held on the front surface thereof via a solenoid 122. The drive of the solenoid 122 is controlled by the controller 116, and the cutting edge of the cutter 121 is brought into contact with and separated from the surface of the workpiece WK by displacing the cutter 121 in the vertical direction in the figure. On both side surfaces of the cutting carriage 120, connecting portions 123a and 123b made of magnets are provided.

  A part of the wire 107 erected in the Y-axis direction is fixed to the upper part of the cutting carriage 120. The wire 107 is connected to a Y-axis direction feed motor 108 whose drive is controlled by a controller 116, and is displaced in the Y-axis direction by the rotational drive of the Y-axis direction feed motor 108. That is, the cutting carriage 120 is displaced in the Y-axis direction by the Y-axis direction feed motor 108 via the wire 107.

  The print carriage 130 has a substantially U-shaped cross section, and includes an ink head unit 131 that prints an image on the surface of the work WK. The ink head unit 131 includes ink heads 132a, 132b, 132c, and 132d provided for each of four different colors of ink. Each of the ink heads 132a to 132d discharges ink supplied from an ink tank (not shown) toward the work WK. That is, the ink head unit 131 prints an image on the surface of the work WK by a combination of four different colors of ink.

  A connecting portion 133 made of a magnet is provided at a position corresponding to the connecting portion 123b of the cutting carriage 120 on the left side surface of the print carriage 130 in the figure. That is, the print carriage 130 is detachably connected to the cutting carriage 120 by the suction forces of the connecting portion 123b and the connecting portion 133. In addition, a receiving metal fitting 134 formed in an L shape is provided on the right side of the print carriage 130 in the figure.

  The stamping carriage 140 is formed in a substantially rectangular parallelepiped shape, and holds a stamping needle 141 that forms a dotted processing mark on the surface of the workpiece WK on the front surface thereof via a solenoid 142. The solenoid 142 is driven by the controller 116 in the same manner as the solenoid 122, and by displacing the stamping needle 141 in the vertical direction in the figure, the cutting edge of the stamping needle 141 strikes the surface of the workpiece WK and releases it. . A connecting portion 143 made of a magnet is provided at a position corresponding to the connecting portion 123a of the cutting carriage 120 on the right side of the stamping carriage 140 in the figure. That is, the stamping carriage 140 is detachably connected to the cutting carriage 120 by the suction forces of the connecting portion 123a and the connecting portion 143. In addition, a receiving metal fitting 144 formed in an L shape is provided on the left side of the stamping carriage 140 in the figure.

  At both ends of the bed 101, flat side frames 109R and 109L for supporting the guide rail 104 are provided in the vertical direction. The side frames 109R and 109L are respectively provided with locking devices 110R and 110L that are hooked on the receiving bracket 134 of the print carriage 130 and the receiving bracket 144 of the stamping carriage 140 to fix the print carriage 130 and the stamping carriage 140, respectively. Yes. The locking devices 110R and 110L include locking solenoids 111R and 111L whose driving is controlled by the controller 116.

  Above the cutting carriage 120, the print carriage 130, and the stamping carriage 140, a long upper cover 112 that constitutes an upper casing of the processing apparatus 100 is provided. Further, side covers 113R and 113L that constitute a housing on each side of the processing apparatus 100 are provided on the outer sides of the side frames 109R and 109L. Among these, on the front surface of the side cover 113R, an operation panel 114 for giving an instruction to the processing apparatus 100 and displaying information from the processing apparatus 100 is provided. Further, below the bed 101, a stand 115 that supports the processing apparatus 100 and can be moved to a position desired by the operator is provided.

  The controller 116 is configured by a microcomputer including a CPU, ROM, RAM, and the like, and in accordance with instructions from an external computer device 118 connected via an interface 117, the X-axis direction feed motor 103 and the Y-axis direction feed motor 108. The solenoid 122, the ink heads 132a to 132d, the solenoid 132, and the locking solenoids 111L and 111R are controlled. The external computer device 118 is a personal computer (so-called personal computer) provided with an input device 118a composed of a keyboard and a mouse and a display device 118b composed of a liquid crystal display. The external computer device 118 operates the processing device 100 by executing a processing program shown in FIG. Control.

  Next, the operation of the processing apparatus 100 configured as described above will be described. First, the operator connects the external computer device 118 and the processing device 100 via the interface 117, and turns on the power to the external computer device 118 and the engraving device 100, respectively. As a result, the external computer device 118 enters a standby state in which it waits for the input of a command from the operator by executing a predetermined program (not shown). Further, the processing apparatus 100 executes a predetermined program (not shown) stored in advance in a ROM in the controller 116 to return the cutting carriage 120, the print carriage 130, and the stamping carriage 140 to their respective origins, and then externally A standby state is waited for an instruction from the computer device 118.

  Next, the operator places the work WK between the grid roll 102 and the pinch rolls 105a and 105b and sets the work WK on the bed 101, and then operates the input device 118a of the external computer device 118, The external computer device 118 is instructed to execute the machining program shown in FIG. This processing program is a program that generates processing data corresponding to a desired image and outputs the processing data to the processing apparatus 100 in order to form an image desired by the operator on the surface of the workpiece WK. In the present embodiment, the workpiece WK is a single sheet having a white surface (surface to be processed).

  In response to this instruction, the external computer device 118 starts the processing program in step S100 and waits for input of image data in step S102. The operator inputs a desired image to the external computer device 118 using an image capturing application. In the present embodiment, a graphic design of an alphabetic character “A” as shown in FIG. 5 is input to the external computer device 118. As a result, image data representing a desired image is stored in the storage device of the external computer device 118. In the present embodiment, the image data is in a raster data (bitmap data) format.

  Next, in step S104, the external computer device 118 generates print processing data, engraving processing data, and cutting processing data based on the image data. The print processing data is data for printing all or part of the desired image on the surface of the workpiece WK by the print carriage 130. The stamping process data is data for forming all or a part of the desired image by the stamping carriage 140 with dot-shaped processing marks. The cutting process data is data for cutting the surface of the workpiece WK by the cutting carriage 120 to form all or part of the desired image.

  In the present embodiment, print processing data and stamping data are generated for the graphic portion PI in the graphic “A” shown in FIG. 5, and cutting processing data are generated for the contour portions OL1 and OL2 in the graphic “A”. In this case, the print processing data is data for printing the shape of the graphic portion PI in a predetermined color (for example, silver). The engraving process data is data for forming a process mark at a depth corresponding to the degree of black and white brightness (luminance) included in the image data. The depth of the processing mark represents the density of the image formed on the workpiece WK. The cutting data is data obtained by converting image data representing the contour portions OL1 and OL2 into a vector data format. It should be noted that in the image data, extraction of a diagram portion (in this embodiment, contour portions OL1 and OL2) for generating engraving data is performed by operating the input device 118a on the external computer device 118. The person may directly instruct, or a known program for extracting a diagram portion may be used.

  Next, in step S106, the external computer device 118 outputs the print processing data generated in step S104 to the processing device 100. The processing device 100 controls the operations of the Y-axis direction feed motor 103, the X-axis direction feed motor 108, the ink head unit 131, and the like based on the print processing data input from the external computer device 118, and the graphic portion in the image data. Specifically, printing of the graphic part PI is started.

  In this case, the controller 116 brings the cutting carriage 120 into contact with the print carriage 130 prior to the start of printing of the graphic portion and releases the lock state of the print carriage 130 by operating the locking solenoid 11R of the lock device 110R. As a result, the print carriage 130 prints an image on the surface of the workpiece WK while being displaced in the X-axis direction together with the cutting carriage 120 while being connected to the cutting carriage 120 by the suction forces of the connecting portions 123b and 133. (See FIG. 3A).

  When the printing of the image is finished, the controller 116 displaces the cutting carriage 120 to the rightmost position in the drawing, and locks the print carriage 130 to the lock device 110R. By printing the graphic part PI in step S106, a silver graphic having a shape corresponding to the shape of the graphic part PI is printed on the surface of the work WK.

  Next, in step S108, the external computer device 118 outputs the stamping processing data generated in step S104 to the processing device 100. The processing device 100 controls the operations of the X-axis direction feed motor 103, the Y-axis direction feed motor 108, the solenoid 142, and the like based on the stamping processing data input from the external computer device 118, and the graphic portion in the image data, specifically Specifically, processing for forming the graphic portion PI by a set of processing marks is started.

  In this case, the controller 116 contacts the cutting carriage 130 with the stamping carriage 140 prior to the formation of the machining trace, and releases the lock state of the stamping carriage 140 by operating the locking solenoid 11L of the lock device 110L. . Thereby, the cutting carriage 140 is displaced in the Y-axis direction together with the cutting carriage 120 while being connected to the cutting carriage 120 by the suction force of the connecting portion 123b and the connecting portion 143. Formation is performed (see FIG. 3B).

  When the formation of the machining trace is completed, the controller 116 displaces the cutting carriage 120 to the leftmost position in the drawing, and locks the stamping carriage 140 to the lock device 110L. As a result of the formation of the machining marks in step S108, a figure is formed on the surface of the workpiece WK, in which the shape of the figure portion PI is represented by a set of point-like machining marks.

  Next, in step S110, the external computer device 118 outputs the cutting processing data generated in step S104 to the processing device 100. The processing apparatus 100 controls each operation of the X-axis direction feed motor 103, the Y-axis direction feed motor 108, the solenoid 122, and the like based on the cutting processing data input from the external computer device 118, and shows a diagram portion of the image data. Specifically, cutting of the contour portions OL1 and OL2 is started. In this case, the controller 116 locks the print carriage 130 and the stamping carriage 140 by the locking devices 110R and 110L, respectively, and performs cutting processing on the surface of the workpiece WK while displacing only the cutting carriage 120 in the Y-axis direction ( (See FIG. 3C).

  When the cutting process is completed, the controller 116 returns the cutting carriage 120 to the origin position and discharges the workpiece WK forward. By cutting the contour portions OL1 and OL2 in step S110, the workpiece WK is cut into a shape corresponding to the contour portion of the graphic portion PI.

  On the other hand, in step S112, the external computer device 118 ends the execution of the machining program and again enters a standby state. Thereby, the processing apparatus 100 also enters a standby state. Then, the worker removes the workpiece WK from the bed 101 and finishes the machining operation. Further, when performing machining on another workpiece WK, the worker sets the other workpiece WK on the bed 101 in the same manner as described above, and then executes the machining program.

  As can be understood from the above description of the operation, according to the above embodiment, after the silver image is printed on the work WK by the ink head unit 131, a dot-like processing mark is formed by the stamping carriage 140. Yes. Therefore, even when a white material is used for the workpiece WK as in the present embodiment, a desired image can be clearly formed. That is, various materials can be used as a workpiece regardless of the reflectance of the material. Further, since the cutting carriage 120 is also provided, the workpiece WK can be cut out and cut in addition to printing an image and forming a processing mark. For this reason, it is possible to form a desired image on the surface of the workpiece WK by abundant expression modes as compared with the conventional processing apparatus.

  Further, when printing and stamping are not performed by the connecting portions 123a, 123b, 132, 142 and the lock devices 110R, 110L, the print carriage 130 and the stamping carriage 140 are placed separately from the cutting carriage 120. Can do. As a result, the load on the Y-axis direction feed motor 108 that displaces the cutting carriage 120 can be suppressed, and it can be expected that the processing accuracy for the workpiece WK is improved and the life of the Y-axis direction feed motor 108 is extended.

  Furthermore, in carrying out the present invention, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the object of the present invention.

  In the above-described embodiment, the processing apparatus 100 includes the cutting carriage 120 that performs the cutting processing of the workpiece WK. However, the cutting carriage 120 is not necessarily required when the workpiece WK is not cut. In the case of the processing apparatus 100 that does not include the cutting carriage 120, the stamping carriage 140 may be configured to be displaced by the Y-axis direction feed motor 108.

  Moreover, in the said embodiment, although the silver image was printed on the surface of the workpiece | work WK, naturally the color to print is not limited to this. Further, the present invention is not limited to a single color, and a plurality of colors may be appropriately arranged, or printing may be performed so as to be overlaid. According to this, it is possible to form a desired image on the surface of the workpiece WK by abundant expression modes as compared with the conventional processing apparatus.

  Further, by increasing the force for pressing the tip of the embossing needle 141 against the surface of the workpiece WK, the processing trace may be formed so as to penetrate the printed color. That is, the depth at which the processing trace is formed is adjusted so that the color printed on the surface of the workpiece WK or the base appears. According to this, a desired image can be formed on the surface of the workpiece by a plurality of colors. That is, a desired image can be expressed by a color other than a metal color such as gold or silver. Thereby, a desired image can be formed on the surface of the workpiece WK by abundant expression modes as compared with the conventional processing apparatus.

  Moreover, in the said embodiment, although the single sheet was used as a to-be-processed object, a long wound sheet | seat may be sufficient. Moreover, materials other than a sheet | seat body, for example, a metal, wood, resin, a ceramic, a cloth material, etc., may be sufficient. That is, the material is not limited as long as the material can form at least image printing and processing marks.

  In the above embodiment, the print carriage 130 and the stamping carriage 140 are separable from the cutting carriage 120. However, the present invention is not limited to this. In other words, these carriages may be integrally configured. According to this, the connection parts 123a, 123b, 132, 142, the lock devices 110R, 110L, and the operation for connecting / disconnecting each carriage 30 are not required.

  In the above embodiment, the Y-axis direction feed motor 108 is configured to displace the cutting carriage 120 in the Y-axis direction. However, the displaced carriage is not limited to the cutting carriage 120. That is, the print carriage 130 or the stamping carriage 140 may be configured to be displaced in the Y-axis direction by the Y-axis direction feed motor 108. In this case, a carriage displaced by the Y-axis direction feed motor, for example, a connecting portion (that is, a first connecting means) that detachably connects the stamping carriage 140 and the cutting carriage 120, and the stamping carriage 140, A connecting portion (that is, a second connecting means) that detachably connects the print carriage 130 is provided. Also by this, the same effect as the above-mentioned embodiment can be expected.

  In the above-described embodiment, the print carriage 130 and the stamping carriage 140 are detachably connected to the cutting carriage 120 that is displaced in the Y-axis direction by the Y-axis direction feed motor 108. The present invention is not limited to this as long as it is detachably connected to the carriage displaced in the Y-axis direction by 108. That is, one of the other two carriages (for example, the print carriage 130) is detachably connected to a carriage (cutting carriage 120) displaced in the Y-axis direction by the Y-axis direction feed motor 108. The other carriage (for example, the stamping carriage 140) of the other two carriages may be detachably connected to the same carriage. Also by this, the same effect as the above-mentioned embodiment can be expected.

  Moreover, in the said embodiment, although connection part 123a, 123b, 133,143 was each comprised with the magnet, if each carriage can be connected so that isolation | separation is possible, it will not be limited to this. For example, it is good also as a structure like the locking devices 110L and 110R instead of a magnet. Also by this, the same effect as the above-mentioned embodiment can be expected.

  Further, in the above-described embodiment, the stamping carriage 140 is configured to form dot-like processing marks on the workpiece WK. However, a linear processing trace may be formed instead of or in addition to the dotted processing trace. Also by this, a desired image can be formed on the surface of the workpiece WK by abundant expression modes as compared with the conventional processing apparatus.

  In the above embodiment, the ink is printed on the surface of the work WK. However, the present invention is not limited to this as long as images such as characters, figures, and colors can be printed on the surface of the work WK. Is not to be done. For example, an image may be printed on the surface of the workpiece WK using light (for example, ultraviolet) curable ink, printing toner, or a laser.

  In the above embodiment, the cutting carriage 120 is configured to cut the workpiece WK using the cutter 121. However, the cutting carriage 120 is not limited to this as long as the workpiece WK can be cut. For example, the workpiece WK may be cut using a tool such as an end mill or a laser. According to this, the cutting process can be performed also on the workpiece WK made of a metal material or the like.

  In the above embodiment, the cutting carriage 120 is displaced in the Y-axis direction and the workpiece WK is displaced in the X-axis direction. However, the present invention is not limited to this as long as the relative positional relationship between each carriage for processing the workpiece WK and the workpiece WK is changed. For example, the position of the workpiece WK may be fixed and each carriage may be displaced.

  Moreover, in the said embodiment, although it processed in order of the printing process, the stamping process, and the cutting process with respect to the workpiece | work WK, it is not limited to this. For example, you may comprise so that a printing process may be performed on the process trace formed by the stamping process. Also by this, a desired image can be formed on the surface of the workpiece WK by abundant expression modes as compared with the conventional processing apparatus.

It is a perspective view showing the whole processing device concerning one embodiment of the present invention. It is a block diagram of the control system which controls the action | operation of the processing apparatus shown in FIG. (A), (B) is a front view showing a state in which two carriages are displaced in a state of being connected in the processing apparatus shown in FIG. 1, and (C) is a single carriage in the processing apparatus shown in FIG. It is a front view which shows a mode that it displaces. 3 shows a flowchart of a machining program executed by an external computer device. It is explanatory drawing which shows the image formed on the surface of the workpiece | work WK by the processing apparatus shown in FIG.

Explanation of symbols

WK ... Workpiece, 100 ... Processing device, 101 ... Bed, 102 ... Grid roll, 103 ... X-axis direction feed motor, 104 ... Guide rail, 108 ... Y-axis direction feed motor, 110R, 110L ... Lock device, 120 ... Cutting carriage , 121 ... cutter, 130 ... print carriage, 131 ... ink head unit, 140 ... stamping carriage, 141 ... stamping needle.

Claims (5)

A processing apparatus for forming the desired image on the surface of the workpiece based on processing data for forming the desired image on the surface of the workpiece,
Printing processing means for printing an image on the surface of the workpiece;
Trace processing means for forming a dotted or linear processing trace on the surface of the workpiece,
A processing apparatus comprising: displacement means for displacing the printing processing means and the trace processing means relative to the workpiece. The processing apparatus according to claim 1, further comprising:
A cutting means for cutting the workpiece,
The displacement means is a processing apparatus that displaces the cutting processing means relative to the workpiece in addition to the printing processing means and the mark processing means. The processing apparatus according to claim 2, wherein
The displacement means is
Drive means for displacing any one of the printing processing means, the trace processing means and the cutting processing means relative to the workpiece;
A first connecting means for detachably connecting one of the two processing means other than the one processing means displaced by the driving means and the one processing means;
A processing apparatus comprising: the other processing means of the other two processing means; and the second connecting means for detachably connecting the one processing means or the one processing means. In the processing apparatus according to claim 3,
The first connecting means and the second connecting means are processing apparatuses that connect each processing means in a separable manner using magnetic force. In the processing apparatus according to any one of claims 2 to 4,
For the workpiece:
First, the image is printed by the printing processing means,
Thereafter, the processing mark is formed by the mark processing means,
Then, the processing apparatus which performs the said cutting | disconnection by the said cutting process means.

Images