KR200455732Y1 - Machine tools - Google Patents

Abstract

The machine tool according to the present invention, the machine tool according to the present invention, the table is provided to move linearly on the bed placed on the floor and the workpiece is placed; A spindle unit equipped with a processing machine for processing a workpiece placed on the table; A first cross rail supporting one side of the spindle device and guiding the linear movement of the spindle device, and a second cross rail supporting the other side of the spindle device and guiding the linear movement of the spindle device. Crossrails; A first column supporting one end of the first crossrail and engaging to guide sliding, a second column supporting one end of the second crossrail and engaging to guide sliding, and the other end of the first crossrail A double column including a third column configured to support and guide the sliding, and a fourth column supporting the other end of the second crossrail and coupled to guide the sliding; And a base fixed to the bottom surface to impart bearing force to the first and second columns and the third and fourth columns, respectively.

Description

Machine Tools {MACHINE TOOLS}

The present invention relates to a machine tool, and more particularly, to a machine tool to improve the stable processing and processing precision of the workpiece.

In general, a machine tool is a machine made to precisely perform machining of a workpiece such as a lathe (Machining Center), a milling machine, a drilling machine, a boring machine, and a grinding machine.

Such a machine tool is provided so that the workpiece can be processed in a desired state while the workpiece is placed on a table and a suitable machine is mounted on the spindle device to allow movement and rotation in up, down, left and right.

The spindle device equipped with the processing machine is fixed to the cross rail so as to be slidable, and the cross rail is fixed to the pillars provided on both sides thereof.

In general, the machining of the workpieces must be done accurately within a very small dimension, so the crossrails and columns should support the spindle system stably and be very insensitive to external loads.

By the way, as the work progresses, the heat deformation of the equipment is generated by the long time work, and the vibration is generated according to the operation of the equipment, which causes a problem that the precision of the work is very degraded.

In particular, in the case of large machine tool equipment, the size of the pillars and the cross rails are increased in size, and thus moving them themselves causes tremendous vibrations, which reduces the precision of machining, and due to the heat generated by the work, The occurrence of machining precision error is very serious.

The present invention provides a machine tool that can stably support the spindle device to minimize the deterioration of machining precision, distribute the load efficiently, and stably reduce vibrations and deformations caused by machining operations.

Machine tool according to the present invention, the table is provided to move linearly on the bed placed on the bottom surface on which the workpiece is placed; A spindle unit equipped with a processing machine for processing a workpiece placed on the table; A first cross rail supporting one side of the spindle device and guiding the linear movement of the spindle device, and a second cross rail supporting the other side of the spindle device and guiding the linear movement of the spindle device. Crossrails; A first column supporting one end of the first crossrail and engaging to guide sliding, a second column supporting one end of the second crossrail and engaging to guide sliding, and the other end of the first crossrail A double column including a third column configured to support and guide the sliding, and a fourth column supporting the other end of the second crossrail and coupled to guide the sliding; And a base fixed to the bottom surface to impart bearing force to the first and second columns and the third and fourth columns, respectively.

Also preferably, the double cross rail may include a first coupling block coupled to one end of the first cross rail and one end of the second cross rail, another end of the first cross rail, and the second cross. It characterized in that it comprises a second coupling block for coupling with the other end of the rail.

Also preferably, the double cross rail may include a seating guide coupled to one end and the other end of each of the first cross rail and the second cross rail so that the side surfaces of the first to fourth columns are slidably coupled thereto. It is characterized by comprising a part.

Also preferably, a first coupling coupled to a rear surface of a seating guide respectively formed at one end of the first crossrail and one end of the second crossrail to fix the first crossrail and the second crossrail to each other. A second coupling block coupled to a block and a rear surface of a seating guide respectively formed at the other end of the first cross rail and the other end of the second cross rail to fix the first cross rail and the second cross rail to each other; It is characterized by including.

Also preferably, a first cover is integrally coupled to the upper ends of the first and second columns, and a second cover integrally coupled to the upper ends of the third and fourth columns. .

Also preferably, the base may be simultaneously coupled to the lower ends of the first column and the second column to simultaneously support the first base and the lower end of the third column and the fourth column. It is characterized in that it comprises a second base coupled to impart a support force to the bottom surface integrally.

Also preferably, a first transfer part provided between the first column and the second column to move one end of the double cross rail in a vertical direction, and provided between the third column and the fourth column to provide the double And a second transfer part configured to move the other end of the cross rail in the vertical direction.

Also preferably, the first transfer part may include a first transfer drive part mounted to the first base and a first transfer screw operated by the first transfer drive part, and the second transfer part may be disposed on the second base. And a second transfer screw mounted to the second transfer driver, and a second transfer screw operated by the second transfer driver.

Also preferably, the first coupling block includes a first coupling hole through which the first transfer screw is coupled, and the second coupling block has a second coupling hole through which the second transfer screw is coupled. The first conveying screw and the second conveying screw are rotated by the driving of the first conveying unit and the second conveying unit, respectively, and the first engaging block and the second engaging block are respectively the first conveying screw and the first conveying screw. It characterized in that it is configured to move in a vertical direction along the conveying screw.

Also preferably, the first cross guide includes a first cross guide formed in the longitudinal direction of the first cross rail, and a second cross guide formed in the longitudinal direction of the second cross rail. And a first guide support provided to slide along the first cross guide and a second guide support provided to slide along the second cross guide.

Also preferably, a first fixing cross bar for connecting and fixing the first column and the third column, and further comprising a second fixing cross bar for connecting and fixing the second column and the fourth column. do.

Also preferably, at least one clamp provided on the double cross rail and provided with a switch unit to press the switch unit and the double cross rail is fixed to the double column, and the double cross rail slides on the double column. It is characterized in that it further comprises an actuator provided to release the pressing of the switch unit when moving and to press the switch unit when the double cross rail stops on the double column.

Also preferably, the spindle device, the main shaft support portion having a ram coupled to the processing machine and provided to be movable in the vertical direction, and a guide support for supporting the ram to move and sliding the double cross rail It includes, The ram is characterized in that each having a load induction surface formed to induce a load distribution between each surface and the surface.

Also preferably, the ram is characterized in that it is configured to have a substantially octagonal cross section by each surface and each load induction plane.

Also preferably, each of the load induction drawing is characterized in that it is formed so as to project a predetermined.

The machine tool according to the present invention basically adopts a double column and a double cross rail structure to stably support the spindle device and minimize the error of vibration and unbalanced load. By effectively distributing and supporting, it has the effect of improving the processing precision.

1 is a perspective view of a machine tool according to an embodiment of the present invention.
2 is a view showing the side of the machine tool shown in FIG.
3 is a perspective view showing the structure of a double cross rail of the machine tool shown in FIG.
FIG. 4 is a plan view illustrating a coupling structure of the double cross rail and the double column illustrated in FIG. 3.
5A and 5B are enlarged views of part A shown in FIG. 4 to illustrate the operation of the clamp in more detail.
6A and 6B illustrate an example of fixing and releasing operations of a cross rail and a column according to the operation of the clamp shown in FIGS. 5A and 5B.
7 is a perspective view showing a ram mounted to the main shaft device of the machine tool according to an embodiment of the present invention.
FIG. 8A illustrates a mechanism when a load is applied to a ram of a machine tool according to the present invention shown in FIG. 6, and FIG. 8B illustrates a mechanism when a load is applied to a ram employed in a general machine tool.

An embodiment of a machine tool according to the present invention will be described in more detail with reference to the drawings.

First, with reference to FIG. 1, a general description of a machine tool according to an exemplary embodiment of the present invention will be described. 1 is a perspective view of a machine tool according to an embodiment of the present invention.

As shown in FIG. 1, a machine tool according to an embodiment of the present invention includes a bed 100, a table 110, a spindle device 400, a double cross rails 510 and 520, and a double column 210 and 220. And 230, 240, and bases 250, 260.

The bed 100 is provided so that the table 110 on which the workpiece is placed can move linearly and is placed on the bottom surface.

The bed 100 is equipped with a driving device (not shown) for linearly moving the table 110 so that the bed cover 120 is provided as shown in FIG. It is preferable to.

When the table 110 moves, the bed cover 120 is folded so as not to interfere with the movement of the table 110.

The spindle device 400 is equipped with a processing machine for processing the workpiece placed on the table 110, so that the rotation or movement of the processing machine is made.

The double cross rail is basically a member provided to support the spindle device 400 simultaneously on both sides, and supports a side of the spindle device 400 and guides the linear movement of the spindle device 400. And a second cross rail 520 supporting the rail 510 and the other side surface of the spindle device 400 to guide the linear movement of the spindle device 400.

The double column is a member that serves to guide the movement of the double cross rails 510 and 520 in the vertical direction while supporting the double cross rails 510 and 520 with respect to the bottom surface.

The double column supports a first column 210 of one end of the first cross rail 510 and is coupled to guide the sliding, and a second column of the second cross rail 520 is supported to guide the sliding. The second column 220 supports the other end of the first cross rail 510 and slides to support the other end of the second cross rail 520. It comprises a fourth column 240 for coupling to guide the.

As described above, when two columns are provided on both sides and the double cross rail is stably supported by the two columns, and the spindle device is stably supported on both sides by the two columns, the spindle device is supported by a single cross rail. It can eliminate the influence of unbalanced load that can be affected and improve the machining precision.

On the other hand, the base 250, 260 is fixed to the bottom surface and is coupled to the lower end of the first column 210 and the second column 220, the first base 250 to provide a support force to the bottom surface integrally And a second base 260 fixed to the bottom surface and coupled to the lower ends of the third column 230 and the fourth column 240 to integrally impart support force to the bottom surface.

The load or vibration applied to each column may vary slightly, and the base may support both columns at the same time so that the load or vibration may be uniform, thereby providing more stable support.

That is, the first base 250 simultaneously supports the first column 210 and the second column 220 integrally with respect to the bottom surface, so that the load applied to each of the first column 210 and the second column 220 may be reduced. The vibration and the like can be supported to be uniform, and the second base 260 can similarly achieve the same effect by integrally supporting the third column 210 and the fourth column 240 on the bottom surface simultaneously.

On the other hand, the machine tool according to an embodiment of the present invention, the first cover 270 is integrally coupled to the upper end of the first column 210 and the second column 220, as shown in Figure 1, The second cover 280 is integrally coupled to the upper ends of the third column 230 and the fourth column 240.

The first cover 270 and the second cover 280 may also induce a uniform distribution such as load or vibration for each of the two columns so that each column can support the double cross rail more stably. Can be.

In addition, the machine tool according to an embodiment of the present invention as shown in Figure 1 is a first fixed cross bar 310 for connecting and fixing the first column 210 and the third column 230, and It is preferable to further include a second fixing cross bar 320 for connecting and fixing the second column 240 and the fourth column 240.

The first base 250 and the first cover 270 stably support the first column 210 and the second column 220, and the second base 260 and the second cover 280 are third When the column 230 and the fourth column 240 are stably supported, the first fixed cross bar 310 stably supports the first column 210 and the third column 230 and the second fixed cross. The bar 320 stably supports the second column 220 and the fourth column 240, thereby supporting each column very stably as a whole and allowing each column to be stabilized so that the double cross rail can also be stably operated. The spindle unit supported by the cross rail also enables stable operation.

On the other hand, with reference to Figure 2 will be described in detail with respect to the structure in which the double cross rail is conveyed with respect to the double column.

FIG. 2 illustrates in more detail a transfer unit providing a driving force capable of moving the double cross rail in a vertical direction.

As shown in FIG. 2, the first transfer parts 610 and 620 are provided between the first column 210 and the second column 220 so that one end of the double cross rail 510, 520, 530 is vertically disposed. More preferably, the first transfer unit is a first transfer unit 610 mounted to the first base 250 and the first transfer unit is operated by the first transfer unit 610 It comprises a screw 620.

Similarly, although not shown in FIG. 2, a second transfer part is provided between the third column 230 (see FIG. 1) and the fourth column 240 (see FIG. 1), and the second transfer part is provided with a second base 260 (FIG. 1) and a second conveying drive part provided on the second conveying part and a second conveying screw operated by the second conveying drive part.

Here, the first transfer screw 620 is coupled to the coupling block 530 of the double cross rail, so that the first transfer screw 620 rotates the first transfer screw 620 by the first transfer driver 610. Coupling block 530 coupled to the () is moved up and down and eventually the entire double cross rail can move in the vertical direction. Of course, at this time, the second transfer drive unit rotates the second transfer screw and the double cross rail can stably move vertically by the first transfer screw and the second transfer screw. The coupling block 530 will be described later.

On the other hand, with reference to Figures 3 and 4 will be described in more detail with respect to the double cross-rail structure according to an embodiment of the present invention.

As shown in FIG. 3 and FIG. 4, the double cross rail has a first cross rail 510 and a second cross rail 520 respectively provided on both sides of the spindle device 400 to support the spindle device 400 on both sides. It is configured to.

At least one first cross guide 511 is provided on a surface of the first cross rail 510 that contacts the main shaft device 400, and a surface of the second cross rail 520 that contacts the main shaft device 400. The second cross guide 521 is provided with at least one, and the main shaft device 400 is fitted to the first guide support 451 and the second cross guide 521 which is engaged with the first cross guide 511. Physics are provided with each of the second guide support portion 452 to guide the linear movement in the left and right directions.

On the other hand, the first cross rail 510 and the second cross rail 520 is composed of a double cross rail as a whole by combining the first coupling block 530 and the second coupling block 540 at each end. .

The coupling part 514 provided on the first cross rail 510 and the coupling part 524 provided on the second cross rail 520 are respectively coupled to the block coupling part 532 of the first coupling block 530. Although not specifically illustrated in FIG. 3, the second coupling block 530 is also fixed by being coupled as described above.

The first coupling block 530 includes a first coupling hole 531 through which the first transfer screw 620 (see FIG. 2) is coupled, and the second coupling block 540 includes a second transfer screw. The first conveying screw and the second conveying screw are rotated by the first conveying driving part (see FIG. 2) and the second conveying driving part, respectively, including a second engaging hole 541 coupled therethrough. The first coupling block and the second coupling block are configured to linearly move in the vertical direction along the first transfer screw and the second transfer screw, respectively.

On the other hand, the one side and the other end of the first cross rail 510 is seated on the side of each of the first column 210 (see FIG. 1) and the third column 230 (see FIG. Guide portions 512 are provided, respectively, and side surfaces of the second column 220 (see FIG. 1) and the fourth column 240 (see FIG. 1) are provided at one end and the other end of the second cross rail 520. A seating guide part 522 is seated and coupled to be slidably provided.

Meanwhile, as shown in FIG. 3, the spindle device 400 includes a ram 420 on which the processor 430 is mounted, a spindle support 410 supporting the ram 420 to be movable, and a spindle drive device (not shown). C), etc.).

On the other hand, as shown in Figure 4, the double cross rail is characterized in that it is provided with a clamp device to be fixed to the double column while stopping the movement while slidingly moving relative to the double column.

That is, as shown in FIG. 4, a portion adjacent to the first column 210 and a portion adjacent to the third column 230 and a second column of the second crossrail 520 are illustrated. The clamp 720 is mounted to the portion adjacent to the 220 and the portion adjacent to the fourth column 240, respectively.

In Figs. 5A and 5B, portions corresponding to such clamps are further enlarged, that is, portions A in Fig. 4 are enlarged.

FIG. 5A illustrates a state in which the crossrail is fixed to the column, and FIG. 5B illustrates a state in which the crossrail can slide with respect to the column.

The clamp 710 has a switch portion 711 and when the switch portion 711 is pressed the clamp 710 actuates the means for securing the crossrail to the column.

Means for allowing the crossrail 520 to be fixed to the column 220 may be implemented in a variety of ways, such as by causing the crossrail 520 and the column 220 to generate friction with each other. The cross rail 520 may be secured to the column 220, and the fixing member (not shown) of the cross rail 520 penetrates the hole of one of a plurality of holes (not shown) formed in the column 220. It is possible to be fixed to). In this case, the fixing member may selectively perform fixing and fixing release by a solenoid or the like.

An example of the means P for allowing the crossrail to be fixed to the column when the clamp 710 is operated in this way is illustrated in FIGS. 6A and 6B.

FIG. 6 (b) shows that the cross rail 520 is fixed to the column 220 by the operation of the means P for clamping the clamp 710, and FIG. 6 (a) shows the clamp. The means (P) for releasing the pressing on the switch unit 711 of the 710 is released and the fixed state is released while the cross rail 520 is slidably movable with respect to the column 220.

As shown in (a) and (b) of FIG. 5, pressing or releasing the switch 711 of the clamp 710 is performed by the actuator 720.

The actuator 720 is mounted to be rotatable by a hinge 721 at a point on the cross rail, and the actuator 720 automatically releases the pressed state of the switch unit 711 when the cross rail is moved and crosses the cross rail. When the rail is to be stopped is preferably configured to automatically press the switch unit 711.

In FIGS. 5A and 5B, the function of the clamp 710 mounted at the portion of the second cross rail 520 and the second column 220 has been described, but as shown in FIG. 4. Since the same clamp is preferably provided at each of the portions joined to each column portion of the first crossrail and the second crossrail, each clamp is preferably configured to operate simultaneously.

On the other hand, with reference to Figures 7 and 8 will be described the structure of the ram 420 constituting the spindle device of the machine tool according to an embodiment of the present invention.

As shown in FIG. 7, the processor 430 is mounted to the mounting portion 421 of the ram 420.

The ram 420 may be subjected to a predetermined external force in the process of the workpiece 430 processing the workpiece (for example, when the cutting is performed, the machine cuts a specific portion of the workpiece). .

As described above, when the external force acts on the ram 420, it is preferable to disperse the external force applied to the ram 420 so as not to affect the machining accuracy.

8 (b) shows a cross-sectional structure of a typical ram 42, which has a rectangular cross section. In the case of the general ram 42, when the external force F acts on the ram 42 in one direction as shown in FIG. 7B, the load b1, b2, b3, and b4 in the drawing receives a concentrated load, that is, the external force F acts. There is a problem in that the concentrated load occurs in a straight line with the direction to be adversely affect the machining precision and the effect of fixing the ram is lost.

Ram 420 employed in the machine tool according to an embodiment of the present invention is characterized in that the cross-section substantially consists of an octagonal shape as shown in Figure 7 and 8 (a).

That is, the ram 420 has load induction planes 423 formed to induce load distribution between each of the planes 422 and 422, respectively, and on each of the planes 422 and each load induction plane 423. It is preferable to be configured to have a substantially octagonal cross section.

Therefore, as shown in (a) of FIG. 8, when the external force F acts in one direction with respect to the ram 420, in addition to the load acting in line with the direction in which the external force F acts, the load induction plane 423 ( A1, a2, a3, and a4 parts) load distribution shown in FIG. 8A can be induced to prevent the occurrence of concentrated load on one side.

As described above, it is possible to minimize the occurrence of machining errors by preventing the concentrated load from occurring on either side due to the load distribution by the external force applied to the ram 420.

The load induction surface 423 may be formed on the protrusion 424 provided to protrude a predetermined time as shown in (a) of FIG.

As described above, the machine tool according to the present invention basically adopts a double column and a double cross rail structure and has a base for supporting the double column integrally to stably support the spindle device and to generate errors in vibration and uneven load. There is an advantage that can be minimized.

100: Bed, 110: Table
210, 220, 230, 240: double column
250, 260: base, 400: spindle
510, 520: double cross rail

Claims (14)

A table provided to linearly move on the bed placed on the floor and on which the workpiece is placed;
A spindle unit equipped with a processing machine for processing a workpiece placed on the table;
A first cross rail supporting one side of the spindle device and guiding the linear movement of the spindle device, and a second cross rail supporting the other side of the spindle device and guiding the linear movement of the spindle device. Crossrails;
A first column supporting one end of the first crossrail and engaging to guide sliding, a second column supporting one end of the second crossrail and engaging to guide sliding, and the other end of the first crossrail A double column including a third column configured to support and guide the sliding, and a fourth column supporting the other end of the second crossrail and coupled to guide the sliding;
A first base that is coupled to the bottom of the first column and the second column at the same time to impart a support force to the bottom surface integrally, and a support force to the bottom surface of the third column and the fourth column at the same time integrally A base comprising a second base for imparting; And
A first cover integrally coupled to the upper ends of the first and second columns, and a second cover integrally coupled to the upper ends of the third and fourth columns,
The double cross rail,
A seating guide part coupled to one end and the other end of each of the first cross rail and the second cross rail to be slidably seated on the side of each of the first to fourth columns, and one end of the first cross rail; And a first coupling block coupled to a rear surface of a seating guide respectively formed at one end of the second crossrail to fix the first crossrail and the second crossrail to each other, and the other end of the first crossrail and the first And a second coupling block coupled to a rear surface of a seating guide respectively formed at the other end of the second cross rail to fix the first cross rail and the second cross rail to each other.
A first transfer driver provided between the first column and the second column to provide a driving force to move one end of the double cross rail in a vertical direction, and a first transfer screw operated by the first transfer driver. A first transfer unit; And
A second transfer driver provided between the third column and the fourth column to provide a driving force to move the other end of the double cross rail in a vertical direction, and a second transfer screw operated by the second transfer driver. Further comprising a second transfer portion,
The first coupling block includes a first coupling hole through which the first transfer screw is coupled, and the second coupling block includes a second coupling hole through which the second transfer screw is coupled. The first conveying screw and the second conveying screw rotate by the first conveying drive part and the second conveying drive part, respectively, and the first engaging block and the second engaging block respectively follow the first conveying screw and the second conveying screw. Machine tool, characterized in that configured to move straight in the vertical direction. delete delete delete delete delete delete delete delete The method of claim 1,
A first cross guide formed in the longitudinal direction on the first cross rail, and a second cross guide formed in the longitudinal direction on the second cross rail,
The spindle device may include a first guide support provided to slide along the first cross guide and a second guide support provided to slide along the second cross guide. The method of claim 1,
A first fixing cross bar connecting and fixing the first column and the third column;
And a second fixing cross bar for connecting and fixing the second column and the fourth column. The method of claim 1,
At least one clamp provided on the double cross rail and having a switch unit to press the switch unit to fix the double cross rail to the double column;
And an actuator provided to release the pressing of the switch portion when the double crossrail slides on the double column, and to press the switch portion when the double crossrail stops on the double column. machine. According to claim 1, The spindle device,
A ram coupled to the processor and provided to be movable in a vertical direction;
A main shaft support part supporting the ram to be movable and having a guide support part for slidingly moving on the double cross rail,
The ram is a machine tool, characterized in that each having a load induction surface formed to induce a load distribution between each surface. The method of claim 13,
And the ram is configured to have a substantially octagonal cross section by each face and each load induction face.

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