WO2009093877A2 - Complex machining center - Google Patents

Abstract

The present invention relates to a complex machining center in which at least one machining unit is mounted on one or more X-direction positioning blocks which are fixed or movable about a base frame, one or more Y-direction positioning blocks arranged on at least one side of the X-direction positioning block, and a Z-direction positioning block connected to the Y-direction positioning block in such a manner that the Z-direction positioning block is movable in the upward and downward directions. The complex machining center is capable of performing carving, precision cutting, V-shape cutting and groove forming work.

Description

Compound processing machine

The present invention relates to a multi-task machine that allows engraving, precision cutting, V-cut formation and the formation of the cut groove are performed by one machine.

In general, a numerically controlled milling machine is equipped with a Z-axis slider with one spindle installed. When machining a workpiece, tools of various functions are fixed to the tool bar in the cutting process order.

Each time a process is completed, the tool post is rotated to replace the tool for the next machining process, and the Z-axis slider and the spindle are driven by a pre-programmed program to perform a series of numerical control operations.

In addition, the machining of such a workpiece is rarely completed in one cutting operation, and often requires repetitive work, and the tool is automatically changed for each operation or the machine tool is changed in a special case.

In connection with this technology, a milling machine is disclosed in the Republic of Korea Utility Model No. 331503, the configuration of which is the main spindle device for automatic replacement chucking of various tools waiting on the rotary tool stand, as shown in Figures 1 and 2 A minor spindle device 20 is installed at one side of the Z-axis slider 30 on which 10 is installed.

At this time, the spindle device 10, 20 is provided with a chuck 15, 25 for mounting the mirror surface processing tool 73 and the tool 70 in the lower portion of the spindle 11, 21 as a general configuration, respectively. .

And, the chuck 25 is located on the lower end of the minor spindle device 20, the tool is mounted on the table 60, the workpiece 60 is mounted compared to the chuck 15 mounted on the main spindle device 10 It consists of a configuration that is installed away from.

However, the milling machine as described above cannot be driven by the minor spindle device 20 when the main spindle device 10 is driven in such a manner that the respective spindle devices 10 and 20 are simultaneously mounted to the Z-axis slider 30. Simultaneous work is impossible, and the operation of the minor spindle device 20 must be performed after the drive of the main spindle device 10 is completed, thus making the work cumbersome, which requires a lot of manpower and time, resulting in enormous disruptions in productivity. There was a problem.

In addition, in the case of mounting and using different tools on the spindle apparatus 10 and 20, only a work by a tool that can be mounted is possible, and when performing various tasks, a separate processing machine having a desired tool should be prepared. There is discomfort.

An object of the present invention for improving the above conventional problems, one or more operations selected from among cutting and engraving operations, precise cutting by plasma or laser, forming V-cuts, processing of the cutting groove by one device It is possible to solve the problem of having to have separate engraving machine and cutting machine, and to be able to engrave or cut precisely with a certain depth at all times, and to carry out engraving work and cutting work selectively by one equipment. To provide a multi-tasking machine that can increase the efficiency of the work.

In addition, it is to provide a multi-task machine that can be used simultaneously while mounting a variety of processing means in one base frame.

The present invention to achieve the above object, a base frame having a work table on which the workpiece to be processed is mounted;

An X-direction positioning block installed on the base frame;

A Y-direction positioning block installed in the X-direction positioning block so as to reciprocate through a transfer means along its longitudinal direction; And

When combined with the Y-direction positioning block provides a multi-task machine consisting of a configuration comprising a Z-direction positioning block, each of which is provided with a plurality of processing means to move up and down separately.

In addition, the present invention, the base frame having a work table on which the workpiece to be processed is placed;

A plurality of X-direction positioning blocks spaced apart from the upper portion of the base frame;

Y-direction positioning blocks which are respectively installed to reciprocate through the conveying means along the longitudinal direction from one side of the X-direction positioning block; And

When combined with the Y-direction positioning block provides a multi-task machine consisting of a configuration comprising a Z-direction positioning block, each of which is provided with a plurality of processing means to move up and down separately.

In addition, the present invention, the base frame having a work table on which the workpiece to be processed is mounted;

An X-direction positioning block installed on the base frame;

A Y-direction positioning block which is separately installed on at least one side of the X-direction positioning block and installed to reciprocate through a transport means along a longitudinal direction thereof; And

When combined with the Y-direction positioning block provides a multi-task machine consisting of a configuration comprising a Z-direction positioning block, each of which is provided with a plurality of processing means to move up and down separately.

In addition, the present invention, the base frame having a work table on which the workpiece to be processed is placed;

A plurality of X-direction positioning blocks spaced apart from the upper portion of the base frame;

A Y-direction positioning block which is separately installed on at least one side of the X-direction positioning block and installed to reciprocate through a transport means along a longitudinal direction thereof; And,

When combined with the Y-direction positioning block provides a multi-task machine consisting of a configuration comprising a Z-direction positioning block, each of which is provided with a plurality of processing means to move up and down separately.

According to the present invention, one or more operations selected from engraving, precision cutting by plasma or laser, forming of V-cut, forming of cutting groove should be performed by one multi-task machine to provide engraving and cutting machines, respectively. Solving the problem, and always precisely engraving or cutting to a certain depth, there is an effect of increasing the efficiency of the work by selectively performing the engraving work and cutting work by a single multi-task machine.

In addition, it is possible to use at the same time while mounting a variety of processing means in one multi-task machine has the effect of improving the cutting efficiency.

1 and 2 are a front view and a main part front view showing a conventional mill.

Figure 3 is a perspective view of a multi-task machine according to the present invention.

Figure 4 is a perspective view of the multi-task machine of the present invention with another working table.

5 is a side view of the multi-task machine according to FIG.

6 is a front view showing the processing means of the multi-task machine according to FIG.

7 is a perspective view showing a work table of the multi-task machine according to FIG.

8 is a perspective view showing a multi-task machine according to another embodiment of the present invention.

9 is a perspective view showing the processing means of the multi-task machine according to FIG.

10 is a front view showing a multi-task machine according to another embodiment of the present invention.

11 is a perspective view showing a multi-task machine according to another embodiment of the present invention.

12 is an operation state diagram of a multi-task machine according to another embodiment of the present invention.

Figure 13 is a front view of a multi-task machine is equipped with a processing means according to another embodiment of the present invention.

14 is a front view showing the processing means of the multi-task machine according to another embodiment of the present invention.

15 to 20 is a view showing a composite machine equipped with a processing means according to another embodiment of the present invention.

21 to 23 is a view showing a composite machine equipped with a processing means according to another embodiment of the present invention.

24 to 26 are views showing the conveying means of the multi-task machine according to the present invention.

27 and 28 are diagrams showing the installation direction of the X-direction positioning block and the work table of the multi-task machine according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention, the base frame 400 and the X-direction positioning block 130 is installed on the upper portion, the Y-direction positioning block 150 is installed on at least one side of the X-direction positioning block 130. At least one Z- direction positioning block 610 or 650 is installed in front of the Y-direction positioning block 150.

In this case, a work table 433 is installed above the base frame 400.

In addition, the work table 433 is installed so as to reciprocate in the longitudinal direction through the transfer means 700 on the upper side of the base frame 400.

On the other hand, the work table 433, the upper side of the rotary table 450 is connected via the second rotating means (470).

At this time, the second rotating means 470 is composed of a combination of the main gear 473 driven as a motor and the driven gear 471 connected to the rotary table 450.

In addition, the X-direction positioning block 130 installed on the upper portion of the base frame 400 is installed to reciprocate through the conveying means 700 in the longitudinal direction of the base frame 400.

At this time, the X-direction positioning block 130, when connected through a plurality of transport means 700 which are spaced apart from the base frame 400 is provided with a plurality of feed so as to be separated.

In addition, the Y-direction positioning block 150, which is connected to one side of the X-direction positioning block 130, is installed in the X-direction positioning block 130 for reciprocating transfer through the transfer means 700.

At this time, the Y-direction positioning block 150, each separated when connected through the transfer means 700 is installed on the upper and lower sides of at least one side of the X-direction positioning block 130, each of the plurality is installed so as to transport do.

In addition, the X-direction positioning block 130 is made of a connection structure of a plurality of first and second variable blocks 131 and 133 to be separated in the vertical direction, the first and second variable blocks 131. 133 is connected as the hydraulic cylinder 131-1.

In addition, the X-direction positioning block 130 is provided with one or more tool posts 500 on one side thereof.

At this time, the tool post 500 is provided with a plurality of support chuck 550 for mounting each tool, the support chuck 550 is made of a plastic material separated from the tool stand body.

In addition, the tool post 500 is installed to be variable in the horizontal and vertical directions through the transfer means 700.

The control unit 300 is installed to control the forward and reverse rotation of the drive motor for driving the transfer means.

In addition, the work table 433, the plurality of suction holes 410 connected to the suction pump (not shown) to support the workpiece (M) is integrally formed on the upper surface.

On the other hand, the work table 433, the support plate 430 is connected to the grid through the support hole 435 so that the heat dissipation is easily made while supporting a minimum area.

The processing means may be directly connected to the Y-direction positioning block 150 having the above configuration, and preferably, the Z-direction positioning blocks 610 and 650 are connected to the Y-direction positioning block 150. Through the processing means is mounted.

At this time, the processing means, the main processing machine 170, laser processing machine 270, plasma processing machine 290, multi-axis processing machine 280, V-cutting machine 250, cutting groove processing machine 210, multi-directional V-cutting machine At least one selected from 220.

The main processor 170 is mounted to any one of the Z-direction positioning blocks 610 and 650 installed in front of the Y-direction positioning block 150 via the transfer means 700.

In addition, the main processor 170 is provided with main spins on which a cutting tool supported by the support chuck 550 of the tool post 500 is mounted.

The laser processor 270 is installed so that the light source of the laser is supplied through the oscillator 205 mounted on the base frame 400 and the reflecting means 230 connected thereto.

In addition, the reflecting means 230 is made of a configuration that the reflector 279 is provided at the corner of the expandable corrugated tube.

At this time, the laser processing machine 270 is connected to the mounting block 277 connected to the Y-direction positioning block 150 through the lifting means 273, the collecting cover 457 to prevent dust from scattering at the lower end. ) Is provided.

The lifting means 273 is a cylinder using pneumatic or hydraulic pressure.

In addition, the multi-axis processing machine 280 is mounted to at least one Z-direction positioning blocks 610 and 650 through the first rotating means 657.

At this time, the first rotation means 657 is composed of a main gear 657-2 connected to the drive motor 657-1 and a driven gear 657-3 provided with the multi-axis machining while being engaged with it.

In addition, the multi-axis cutter 280 is connected to the multi-cutter 285 so that a rotational force is transmitted from different angles while a plurality of tools are installed to rotate at the same time through one drive motor.

The V-cutting machine 250 is installed in the Z-direction positioning block 610 connected to the front of the Y-direction positioning block 150 through the transfer means 700, and the plurality of first V-cutters 255 are transferred. It is installed to be transported in the left, right and up and down directions through the means.

And, the multi-directional V-cutting machine 220, the Z-direction positioning block 610 is connected to the front of the Y-direction positioning block 150 or to the Y-direction positioning block 150 through a conveying means. 650).

At this time, the multi-directional V-cutting machine 220 is connected to the Y-direction positioning block 150 having a L-shape so that a plurality of second V-cutting machine 223 is provided to allow selective operation at different angles, or hydraulic or pneumatic It is installed to move up and down along the guide groove 225 as the cylinder 223 operating by.

The cutting groove processing machine 210 is connected to the Y-direction positioning block 150 having an L-shape to allow selective operation at different angles to guide the guide groove 225 as a cylinder 223 operated by hydraulic or pneumatic pressure. It is installed to rise and fall along.

In addition, in the Z-direction positioning blocks 610 and 650 connected to the cutting groove processing machine 210 and the Y-direction positioning block 150 in front of the Y-direction positioning block 150 through a conveying means. Is mounted.

In addition, the cutting groove 210 is made of a plurality of blades to maintain a constant interval while allowing the free rotation in the Z-direction positioning block 610.

On the other hand, the cutting groove 210 is provided with a plurality of cutting grooves 210 in the circumferential direction so that the blades have different intervals through the variable means 360 in the Z-direction positioning block 610. do.

At this time, the variable means 360, the cutting groove processing machine 210 is connected to the circumferential direction, respectively, the rotary plate 361 having a first gear on one side and the second gear 365 is meshed with the first gear is driven. It consists of a configuration connected to the motor 363.

The transfer means 700 is composed of a driving motor 703, a rotary gear 705 and the connecting block 707, the LM guide 701 is meshed with the rotary gear 705.

In addition, the transfer means 700 may use a cylinder which operates by hydraulic pressure or pneumatic pressure.

In this case, the drive gear 703 may use a rack gear 713 or a pinion gear 715.

In addition, the transfer means 700 is made of a drive pulley 714 and driven pulley 716 to which the drive motor 703 is connected, and a belt 718 that is fixed to the work table 433 while being connected thereto.

At this time, the pulley sprocket wheel, the belt may be replaced by a chain corresponding to the sprocket wheel.

The operation of the present invention having the above configuration will be described.

3 to 28, when the workpiece (M) is supported on the work table 433 is fixed to the upper portion of the base frame 400 through the conveying means 700 along the longitudinal direction of the base frame 400 The direction positioning block 130 is reciprocated.

At this time, the X-direction positioning block 130 is connected to the Y-direction positioning block 150 is transferred to the left and right through the conveying means 700, and connected to the front of the Z-direction positioning block provided with the processing means When the 610 and 650 are raised and lowered, the cutting operation is performed on the surface of the workpiece.

In addition, the work table 433 installed on the upper side of the base frame 400 is to be reciprocated from the base frame 400 through the transfer means 700, and the X-direction positioning block 130 is fixed or transported It performs cutting and other work on the surface of workpiece while being transported in the same or opposite direction.

On the other hand, the work table 433 which is fixed or transported on the upper side of the base frame 400 as described above is a workpiece that is fixed or moved by the rotary table 450 is connected through the second rotating means 470 on the upper side ( M) will be rotated at the same time.

In addition, the work table 433 may have various shapes corresponding to the processing means used.

In the case of a general workpiece, the work table 433 is provided with a plurality of adsorption holes 410 on the upper surface on which the workpiece M is supported so as to support the workpiece while driving the suction pump connected thereto.

When the plurality of support plates 430 use the work table 433 in which the support holes 435 are inserted into a lattice shape, they are generated when the main processor 170, the laser processor 270, and the plasma processor 290 are used. It is possible to easily deal with dust and heat.

In addition, the X-direction positioning block 130 has a structure in which a plurality of first and second variable blocks 131 and 133 are connected to each other, and thus the X-direction positioning block 130 operates when the hydraulic cylinder 131-1 is operated. The heights of the Y-direction positioning blocks 150 and Z-direction positioning blocks 610 and 650 connected to 130 are adjusted.

On the other hand, the X-direction positioning block 130, the configuration is installed in a plurality of positions spaced apart from both sides of the upper portion of the base frame 400 in the same direction or in the opposite direction through the respective conveying means 700 connected thereto. Each is transported.

At this time, each of the X-direction positioning blocks 130 and Z-direction positioning blocks 610 and 650 are provided in each of the X-direction positioning blocks 130 to be fixed or transported to the base frame 400. .

On the other hand, as described above, at least one Y-direction positioning block 150 installed on the upper side of the base frame 400 is also separately installed on at least one side of the X-direction positioning block 130 and connected to each other. It is installed to be transported in the same direction or in the opposite direction through the conveying means 700.

At this time, the processing means may be connected to the front of the Y-direction positioning block 150, the Z-direction positioning block 610 is connected to the front of the Y-direction positioning block 150 through the transfer means 700. The processing means may be connected to 650.

In addition, one or more tool posts 500 having a support chuck 550 are installed on the X-direction positioning block 130 so as to move left, right, and up and down to facilitate a desired tool on the main spindle of the main processing machine 170. To be installed properly.

At this time, the support chuck 550 is made of a plastic material that is separated from the tool stand body while maintaining the elasticity can be used to replace the hand in case of breakage.

Subsequently, the operation of the processing means provided in front of the Y-direction positioning block 150 or the Z-direction positioning blocks 610 and 650 as described above will be described.

The processing means of the present invention, the main processing machine 170 and the other one or more processing means is mounted at the same time in front of the Z-direction positioning blocks 610 and 650, it is possible to perform a variety of operations by one multi-task machine .

In addition, one or a plurality of the processing means are respectively installed in the X-direction positioning block 130 separately installed on the upper side of the base frame 400, or Y-direction position separately installed in the X-direction positioning block 130. When installed in each of the decision block 150, a variety of operations are possible by a single multi-task machine.

In addition, the processing means, the individual processing means through the X, Y direction positioning blocks (130, 150) and Z direction positioning blocks (610, 650) connected to the upper side of the base frame (400). When connected, three-dimensional movement on the upper side of the workpiece can be performed for each desired machining operation.

The laser processing machine 270 is supplied with a light source of the laser through the oscillator 205 mounted on the base frame 400 and the reflecting means 230 connected thereto, thereby minimizing the generation of dust or cutting chips. It will be.

At this time, the reflecting means 230, the reflector 279 is provided at each corner of the expandable corrugated tube, it is easy to supply the laser light source supplied from the oscillator 205 even when bent at various angles.

In addition, the multi-axis processing machine 280 is mounted in front of the at least one Z-direction positioning blocks 610 and 650 through the first rotating means 657 to incline in the vertical direction of the upper surface of the workpiece (M). This is possible.

In addition, the multi-axis processing machine 280, through the multi-cutter (285) during the rotation of the drive motor can be carried out simultaneously or selectively at the same time or selectively.

When the V-cutting machine 250 is connected to the Y-direction positioning block 150 or to the Z-direction positioning block 610 connected to the Y-direction positioning block 150 through the conveying means 700. Each of the first V cutters 255 performs a plurality of V cut forming operations.

In addition, the multi-directional V-cutting machine 220 is configured to maintain a constant angle as described above V-cutting machine 220 along the guide groove 225 during operation of the cylinder 223 operating by hydraulic or pneumatic When lowering, the V cut forming work in one direction or the other direction is quickly performed as the second V cutter 223.

Subsequently, the cutting groove processing machine 210 is composed of a plurality of blades to be rotated freely, connected to the Y-direction positioning block 150, or connected to the Y-direction positioning block 150 through the conveying means 700. When it is connected to the Z-direction positioning block 610 is to form a groove in the grid (M) at the same time.

On the other hand, the cutting groove 210 is provided with a plurality of cutting groove 210 is formed in the circumferential direction of the blades of different intervals through the variable means 360 in the Z-direction positioning block 610. It is possible to quickly perform the cutting groove processing of the desired interval without rotating the cutting groove processing machine 210 when rotating.

At this time, the variable means 360, the rotary plate 361 is rotated during the rotation of the drive motor 363 so that each of the cutting groove processing machine 210 having a different interval is accurately positioned in the working position.

Through the above configuration, one or more machining operations selected from machining using plasma or laser, machining using tools, forming V-cuts and forming cut-out grooves can be performed through one compound processing machine. While maximizing work efficiency.

The present invention is applied to a processing machine to perform the work of carving, precision cutting, forming the V-cut, forming the cut groove simultaneously or selectively by a single machine, such as woodworking or plastic and metal.

Claims (38)

1. A base frame having a work table on which a work piece is placed;

   An X-direction positioning block installed on the base frame;

   A Y-direction positioning block installed in the X-direction positioning block so as to reciprocate through a transfer means along its longitudinal direction; And

   And a Z-direction positioning block, each of which is provided with a plurality of machining means which are divided up and down when connected to the Y-direction positioning block.
2. The multi-task machine according to claim 1, wherein the work table is installed to allow reciprocation in the longitudinal direction through a transfer means on an upper side of the base frame.
3. According to claim 1 or 2, wherein the work table, the rotary table is connected to the upper side through the second rotating means,

   And said second rotating means comprises a combination of a main gear driven as a motor and a driven gear connected to a rotating table.
4. The multi-task machine according to claim 1, wherein the X-direction positioning block is installed at least one reciprocating path through a transfer means in the longitudinal direction of the base frame.
5. The method of claim 1, wherein the Y-direction positioning block is installed on at least one side of the X-direction positioning block, the lower side is provided with at least one processing means while being installed for each reciprocating transfer through the transfer means. Compound processing machine characterized by the above-mentioned.
6. The method of claim 1 or 4, wherein the X-direction positioning block is provided with one or more tool posts on one side thereof,

   The tool post is provided with a plurality of support chuck for mounting a tool, the support chuck is a composite processing machine, characterized in that made of a plastic material separated from the tool stand body.
7. The method of claim 1 or 5, wherein the Y-direction positioning block is made of a connecting structure of the first and second variable blocks separated in the vertical direction, wherein the first and second variable blocks are connected as a hydraulic cylinder Compound processing machine characterized by the above-mentioned.
8. The complex processing machine according to claim 1, wherein the work table is formed integrally with the upper surface of a plurality of adsorption holes connected to the adsorption pump to support the workpiece.
9. The multi-task machine according to claim 1, wherein the work table is connected to a lattice through a support hole so that heat dissipation is easily performed while supporting a minimum area.
10. The multi-task machine according to claim 1, wherein the Z-direction positioning block is provided at one side thereof with a main processing machine which is one of the processing means and at least one other processing machine selected from the processing means.
11. The processing device according to claim 1, 5 or 10, wherein the processing means is at least one selected from a main processing machine, a laser processing machine, a plasma processing machine, a multi-axis processing machine, a V-cutting machine, an incision groove processing machine, and a multi-directional V-cutting machine. Compound processing machine, characterized in that.
12. The method of claim 11, wherein the laser processing machine, the oscillator and reflecting means,

    The reflecting means is a composite processing machine, characterized in that consisting of a configuration provided with a reflecting mirror at the corner of the expandable and expandable corrugated pipe.
13. According to claim 11, The multi-axis machining machine is connected to the Z-direction positioning block through the first rotating means,

    The first rotating means is a composite processing machine comprising a main gear connected to the drive motor and a driven gear provided to the multi-axis processing machine while being engaged with it.
14. 14. The multi-task machine according to claim 13, wherein the multi-axis machining machine is installed such that rotational force is transmitted from different angles while a plurality of tools are installed to rotate at the same time through one driving motor.
15. 12. The method of claim 11, wherein the V-cutting machine is connected to the Y-direction positioning block or the Z-direction positioning block, the plurality of V-cutters are installed so as to transfer in the left, right or up, down direction through the transfer means. Compound processing machine characterized by the above-mentioned.
16. 12. The multi-directional V-cutting machine according to claim 11, wherein the multi-directional V-cutting machine is connected to a Y-direction positioning block or a Z-direction positioning block.

    The multi-task machine is connected to the Y-direction positioning block having a L-shape to allow selective operation at different angles, and is installed to move up and down along the guide groove during operation of a cylinder operated by hydraulic pressure or pneumatic pressure.
17. 12. The method of claim 11, wherein the cutting groove processing machine is connected to the Y-direction positioning block or Z-direction positioning block is installed to move up and down along the guide groove when operating as a cylinder operating by hydraulic or pneumatic,

    And a plurality of blades freely rotated in the Y-direction positioning block or the Z-direction positioning block while maintaining a constant interval.
18. The cutting groove processing machine according to claim 17, wherein the cutting groove processing machine includes a plurality of cutting groove processing machines in the circumferential direction so that the blades have different intervals through the variable means in the Z-direction positioning block.

    Wherein the variable means, the cutting machine is coupled to the circumferential direction, respectively, the rotary plate having a first gear and a second gear meshing with the first gear is coupled to the drive motor is driven, characterized in that the drive.
19. The method according to any one of claims 1, 2, 4, 5 or 15, wherein the conveying means includes a rotary gear to which the drive motor is connected and a connecting block engaged with the rotary gear, LM guide. A composite processing machine comprising:
20. The composite processing machine according to any one of claims 1, 2, 4, 5, and 15, wherein the transfer means is a cylinder operated by hydraulic pressure or pneumatic pressure.
21. 20. The multi-task machine according to claim 19, wherein the drive gear is selected from rack gears and pinion gears.
22. The method according to any one of claims 1, 2, 4, 5 or 15, wherein the transfer means is connected to the drive pulley and the driven pulley to which the drive motor is connected and fixed to the work table while being connected thereto. A composite processing machine comprising as a belt.
23. The method of claim 11, wherein the processing means, the X-direction positioning block to be transported about the base frame, the Y-direction positioning block to be transported around the X-direction positioning block, the Y-direction positioning block is transported about the A compound processing machine characterized in that it is connected to a control unit for controlling the transfer of the Z-direction positioning block.
24. A base frame having a work table on which a work piece is placed;

    An X-direction positioning block spaced apart from an upper portion of the base frame;

    A Y-direction positioning block installed on the at least one side of the X-direction positioning block so as to reciprocate through a conveying means along its longitudinal direction; And

    And a Z-direction positioning block, each of which is provided with a plurality of machining means which are divided up and down when connected to the Y-direction positioning block.
25. 25. The multi-task machine as claimed in claim 24, wherein the work table is installed to allow a reciprocating transfer in the longitudinal direction through a transfer means above the base frame.
26. The composite processing machine according to claim 24, wherein the processing means is at least one selected from a main processing machine, a laser processing machine, a plasma processing machine, a multi-axis processing machine, a V-cutting machine, an incision groove processing machine, and a multi-directional V-cutting machine.
27. 25. The complex processing machine according to claim 24, wherein the X-direction positioning block is installed to reciprocate through a conveying means in the longitudinal direction of the base frame.
28. 28. The complex processing machine according to any one of claims 24, 25 and 27, wherein the transfer means comprises a rotary gear to which a drive motor is connected, a connecting block to be engaged with the rotary gear, and an LM guide. .
29. A base frame having a work table on which a work piece is placed;

    An X-direction positioning block installed on the base frame;

    A Y-direction positioning block disposed separately on at least one side of the X-direction positioning block and installed to reciprocate through a transfer means along a longitudinal direction thereof; And

    And a Z-direction positioning block, each of which is provided with a plurality of machining means which are divided up and down when connected to the Y-direction positioning block.
30. 30. The multi-task machine as claimed in claim 29, wherein the work table is installed to allow reciprocating in the longitudinal direction through a conveying means above the base frame.
31. The composite processing machine according to claim 29, wherein the processing means is at least one selected from a main processing machine, a laser processing machine, a plasma processing machine, a multi-axis processing machine, a V-cutting machine, an incision groove processing machine, and a multi-directional V-cutting machine.
32. 30. The complex processing machine according to claim 29, wherein the X-direction positioning block is installed to reciprocate through a conveying means in the longitudinal direction of the base frame.
33. 33. The complex processing machine according to any one of claims 29, 30 and 32, wherein the transfer means comprises a rotary gear to which a drive motor is connected, a connecting block to be engaged with the rotary gear, and an LM guide. .
34. A base frame having a work table on which a work piece is placed;

    A plurality of X-direction positioning blocks spaced apart from the top of the base frame;

    A Y-direction positioning block which is separately installed on at least one side of the X-direction positioning block and installed to reciprocate through a transfer means along a longitudinal direction thereof; And

    And a Z-direction positioning block, each of which is provided with a plurality of machining means which are divided up and down when connected to the Y-direction positioning block.
35. 35. The complex processing machine according to claim 34, wherein the work table is installed to allow reciprocating in the longitudinal direction through a conveying means above the base frame.
36. 35. The complex processing machine according to claim 34, wherein the processing means is at least one selected from a main processing machine, a laser processing machine, a plasma processing machine, a multi-axis processing machine, a V-cutting machine, an incision groove processing machine, and a multi-directional V-cutting machine.
37. 35. The complex processing machine according to claim 34, wherein the X-direction positioning blocks are installed to reciprocate in the longitudinal direction of the base frame, respectively, via a conveying means.
38. 38. The complex processing machine according to claim 34, 35 or 37, wherein the transfer means comprises a rotary gear to which a drive motor is connected, a connecting block to be engaged with the rotary gear, and an LM guide.

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