KR20140091884A - Apparatus for cutting stone panel - Google Patents

Abstract

The present invention relates to an apparatus for cutting a stone panel capable of cutting a stone panel by a width as narrow as 150 mm. According to the apparatus for cutting a stone panel, a shaft (20) having a screw is arranged in a cutting frame (10) having an ″H″ shaped cross section, and multiple cutting heads (30) are combined with the shaft (20) and arranged in the cutting frame (10) at predetermined intervals (S). According to the present invention, one end of the shaft (20) is mounted on a sliding block (40), the sliding block (40) is mounted on one end of the cutting frame (10), the other end of the shaft (20) is mounted on a shaft transferring device (50), and the shaft transferring device (50) is mounted on the other end of the cutting frame (10).

Description

{APPARATUS FOR CUTTING STONE PANEL}

The present invention relates to a slab material cutting apparatus capable of cutting a slab material to a narrow width (about 150 mm). More specifically, one end of a shaft is supported on a sliding block mounted on a cutting frame without rotation, The present invention relates to a slab material cutting apparatus mounted on a shaft feeder mounted on a cutting frame and capable of being moved to the left and right without rotating the shaft.

Korean Patent No. 10-1068643 (registered on September 22, 2011), "slab narrow-width cutting device" is introduced.

Wherein the first hanger frame on which the main cutting head is mounted is mounted on the railcar, the rail car is transportably mounted on the monorail of the orthogonal type stone cutting machine, and the second hanger frame on which the narrowing head is mounted Wherein the slider is mounted on a monorail of an orthogonal stone cutter so that the narrower head is disposed relatively forward relative to the main cutting head and the second hanger frame of the main cutting head and the second The hanger frame is detachably coupled so that the distance between the cutter of the main cutting head and the cutter of the narrow head is minimized.

However, other configurations of the slab narrow-width cutting apparatus for cutting the slab into narrow widths may be possible.

Therefore, it is an object of the present invention to provide a method of manufacturing a slide fastener, in which one end of a shaft is supported by a sliding block mounted on a cutting frame without rotation, the other end of the shaft is mounted on a shaft transfer device mounted on a cutting frame, The present invention provides a slab material cutting apparatus capable of cutting a slab material to a predetermined width and then slicing the slab material into narrow slabs.

According to an aspect of the present invention, there is provided a cutting frame having a cutting frame having an "H" sectional shape, a shaft having a spiral formed therein, a plurality of cutting heads fixed to the shaft, Wherein one end of the shaft is mounted on the sliding block, the sliding block is mounted on one end of the cutting frame, the other end of the shaft is mounted on the shaft feeding device, and the shaft feeding device is mounted on the other end of the cutting frame .

The sliding block is characterized in that a slider is movably mounted on a guide rail provided at an upper end of a vertical portion of a cutting frame, a block is suspended on a lower surface of the slider, and one end of the shaft is mounted to the center hole of the block by power lock means Of the slab material.

As another example, the sliding block may have a structure in which a spline block is mounted on one end of a cutting frame, a spline hole is formed in the spline block, a spline shaft is fitted in the spline hole, and one end of the spline shaft is connected to the shaft by coupling .

As another example, the sliding block may be such that the sliding block has a key block mounted at one end of the cutting frame, a connecting shaft is fitted to the hole of the key block, the connecting shaft and the key block are coupled by a key, And is connected to the shaft by the coupling.

The shaft transfer device is characterized in that a fixed box is fixed to a cutting frame, a cylindrical member is rotatably mounted by bearings inside the fixed box, a hollow portion is formed in the cylindrical member, a spiral fastening portion is formed on the inner peripheral surface of the cylindrical member, A worm gear is formed on an outer circumferential surface of a cylindrical member, a worm gear is interlocked with a worm, and a worm is connected to a drive shaft of a motor mounted in an upright state on a fixed box .

The stationary box is an internal stationary type, and a flange portion is formed at a lower side of the side surface, and the flange portion is fixed to the horizontal portion of the cutting frame by bolts.

Alternatively, the stationary box is an outer stationary type, and a bracket is attached to the side surface, and the side end portion of the bracket is fixed to the side end of the cutting frame by bolts.

As another example, the shaft transfer device is characterized in that the cylinder is mounted on the side of the frame, and the connecting rod of the cylinder is connected to the other end of the shaft.

As another example, the shaft transfer device is characterized in that the pinion driven by the motor is engaged with a rack gear connected to the other end of the shaft.

Thereby, the slab material cutting apparatus according to the present invention has the effect of cutting the slab material to a predetermined width, and then cutting the slab material into narrow slabs again.

FIG. 1 is a perspective view of a slab material cutting apparatus according to the present invention, in which cutting heads are arranged at predetermined intervals on a cutting frame.
FIG. 2 is a plan view showing a slab material cutting apparatus according to the present invention, in which the shaft is moved by S / 2 from the state (a) to the state (b) by the shaft transfer device.
3 is a cross-sectional view taken along the line AA of Fig. 1 showing the sliding block according to the first embodiment.
4 is a plan view showing a sliding block according to the second embodiment.
5 is a side view of the sliding block according to the second embodiment seen in the direction C of FIG.
6 is a plan view showing a sliding block according to the third embodiment.
7 is a side view of the sliding block according to the third embodiment seen in the direction D of FIG.
8 is a cross-sectional view taken along the line BB of Fig. 1 showing the shaft transfer apparatus according to the first embodiment.
9 is a cross-sectional view taken along the line EE of Fig. 8 showing the shaft transfer apparatus according to the first embodiment.
10 is a plan view showing an example in which the shaft conveying apparatus according to the first embodiment is externally mounted and disposed on the outer side of the other end of the cutting shaft.
11 is a plan view showing a shaft transfer apparatus according to the second embodiment.
12 is a plan view showing a shaft transfer apparatus according to the third embodiment.

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

1 and 2, a slab material cutting apparatus according to the present invention is a slab material cutting apparatus in which a shaft 20 having a spiral formed therein is disposed on a cutting frame 10 having an "H" sectional shape, The head 30 is fastened and arranged at a predetermined interval S in the cutting frame 10. [

As a result, the cutting width of the slab material is determined by the spacing S between the cutting heads 30 fastened to the shaft 20. At this time, due to the size of the cutting head 30, the minimum cutting width of the slab material (usually about 300 mm) is determined. Therefore, in order to cut the slab material to a narrow width (usually about 150 mm) which is about half of the minimum cutting width (usually about 300 mm), a separate additional structure is required.

In the present invention, one end of the shaft 20 is mounted on the sliding block 40, the sliding block 40 is mounted on one end of the cutting frame 10, and the other end of the shaft 20 is mounted on the shaft transfer device 50 And the shaft transfer device 50 is mounted on the other end of the cutting frame 10. [

2 (a), the cutting head 30 is arranged on the shaft 20 at a cutting width interval S at which the slab material is to be cut, (Not shown) is cut first and then the shaft 20 is rotated by the shaft transfer device 50 so that the shaft 20 is shifted to the left half of the cutting width S / 2 (FIG. 2 So that the cutting head 30 can cut again the already cut slab material to a half width.

Although the present invention has been described with respect to the width of the cutting width of the slab material as a half of the width of the slab material for the sake of convenience of the above description, the present invention is not limited to this and the cutting width of the slab material can be narrowed or broadened It will be appreciated by those of ordinary skill in the art that the present invention can be applied to both a cutter in which a plurality of cutting heads are arranged such as a terminator, a transverse section, an orthogonal cutter, a conveyor cutter, a fixed cutter, It will be understood that they fall within the scope of the claims of the invention.

Since the cutting head 30 is not a gist of the present invention, a detailed description thereof will be omitted for the sake of explanation.

3, the sliding block 40 is configured such that the slider 41 is movable in the guide rails 13 and 14 provided at the upper ends of the vertical portions 11 and 12 of the cutting frame 10, And the block 42 is suspended on the lower surface of the slider 41. One end of the shaft 20 is mounted to the center hole of the block 42 by the power lock means 43. [

The sliding block 40 constructed as described above is configured such that one end of the shaft 20 is fixed to the power lock means 43 to prevent the shaft 20 from rotating, The slider 41 is moved along the guide rails 13 and 14 of the cutting frame 10 when the shaft 20 is moved by the feeder 50. [

4 and 5, the sliding block 40 includes a spline block 410 mounted on one end 11 of the cutting frame 10, a spline block 410 attached to the spline block 410, A spline shaft 420 is fitted in the spline hole 417 and one end of the spline shaft 420 is connected to the shaft 20 by a coupling 430. [

Thus, the shaft 20 is prevented from rotating, but it can be slid in the left-right direction as indicated by the arrow 21 in Fig. 4 by the spline shaft 420. [

6 and 7, in the third embodiment, the sliding block 40 is configured such that the key block 450 is mounted on one end of the cutting frame 10, and the sliding block 40 is inserted into the hole 452 of the key block 450 The connection shaft 460 is engaged and the connection shaft 460 and the key block 450 are coupled by the key 470 and one end of the connection shaft 460 is connected to the shaft 20 by the coupling 480 .

By this, the shaft 20 is prevented from rotating, but it can be slid in the lateral direction as indicated by the arrow 22 in Fig. 6 by the connection shaft 460. [

8 and 9, in the first embodiment, the shaft transfer device 50 has a fixed box 51 fixed to a cutting frame 10, a bearing 52 disposed inside a fixed box 51, A hollow portion is formed in the cylindrical member 53 and a spiral fastening portion 54 is formed on the inner peripheral surface of the cylindrical member 53 and the spiral of the spiral of the cylindrical member 53 The worm gear 55 is formed on the outer circumferential surface of the cylindrical member 53 with the helical portion 21 of the shaft 20 fastened to the fastening portion 54 and the worm gear 55 is interlocked with the worm 56, And the worm 56 is connected to the drive shaft 58 of the motor 57 mounted on the fixed box 51 in an inverted state.

When the worm 56 is rotated in either direction by the motor 57, the worm wheel 55 is interlocked with the worm 56, and the worm wheel 55 is formed The cylindrical member 53 is rotated so that the cylindrical member 53 is engaged with the shaft 20 and the shaft 20 is moved in the direction of the arrow 25 in Fig. When the worm 56 is rotated in the opposite direction by the motor 57, the worm wheel 55 is interlocked with the worm 56 and the cylindrical member 53 having the worm wheel 55 is rotated in the opposite direction So that the shaft 20 is moved in the direction opposite to the arrow 25 in Fig.

8, the stationary box 51 is an internal stationary type, and a flange portion 59 is formed at the lower side of the side surface. The flange portion 59 is fixed to the horizontal (15).

10, the stationary box 51 is an external stationary type, and a bracket 61 is mounted on a side surface of the stationary box 51. A side end portion 62 of the bracket 61 is fixed to a bolt (not shown) And is fixed to the side end of the cutting frame 10.

Referring to Fig. 11, as a second embodiment, the shaft transfer device 50 is mounted on the side of the frame 10, and the connecting rod 510 of the cylinder is connected to the other end of the shaft 20 .

As a result, when the connecting rod 510 is pulled into the cylinder, the shaft 20 and the cutting head 30 are moved in the direction of arrow 26 and the connecting rod 510 is pulled out of the cylinder, And the cutting head 30 are moved in the direction opposite to the arrow 26. [

Referring to FIG. 12, in the third embodiment, the shaft transfer device 50 is configured such that a pinion 530 driven by a motor (not shown) engages with a rack gear 535 connected to the other end of the shaft 20 do.

The rack gear 535 is connected to the shaft 20 by a coupling 537.

As a result, when the pinion 530 is rotated in one direction, the rack gear 535 of the shaft 20 is interlocked with the pinion 530, the shaft 20 is moved in the direction of the arrow 24, The rack gear 535 of the shaft 20 is interlocked with the pinion 530 so that the shaft 20 is moved in the direction opposite to the arrow 24 when the shaft 530 is rotated in the opposite direction.

10: Cutting frame 20: Shaft
30: Cutting head 40: Sliding block
50: Shaft feed device

Claims (9)

A shaft 20 having a spiral formed therein is disposed on a cutting frame 10 having an "H" sectional shape. A plurality of cutting heads 30 are fastened to the shaft 20, S), comprising:
One end of the shaft 20 is mounted on the sliding block 40 and the sliding block 40 is mounted on one end of the cutting frame 10 and the other end of the shaft 20 is mounted on the shaft transfer device 50, And the shaft transfer device (50) is mounted on the other end of the cutting frame (10).
The method according to claim 1,
The slider 41 is movably mounted on the guide rails 13 and 14 provided on the upper ends of the vertical portions 11 and 12 of the cutting frame 10 and the slider 41 is mounted on the lower surface of the slider 41 Characterized in that the block (42) hangs and one end of the shaft (20) is mounted to the center hole of the block (42) by the power lock means (43).
The method according to claim 1,
The sliding block 40 is configured such that a spline block 410 is mounted on one end 11 of the cutting frame 10 and a spline hole 417 is formed in the spline block 410. A spline hole 417 is formed in the spline hole 417, (420) is fitted, and one end of the spline shaft (420) is connected to the shaft (20) by a coupling (430).
The method according to claim 1,
The sliding block 40 has a key block 450 mounted on one end of the cutting frame 10 and a connecting shaft 460 fitted into a hole 452 of the key block 450, Wherein the coupling shaft (460) and the key block (450) are coupled, and one end of the coupling shaft (460) is connected to the shaft (20) by a coupling (480).
The method according to claim 1,
The shaft transfer device 50 is configured such that a fixed box 51 is fixed to a cutting frame 10 and a cylindrical member 53 is rotatably mounted in a fixed box 51 by a bearing 52, A hollow portion is formed in the member 53 and a helical fastening portion 54 is formed on the inner circumferential surface of the cylindrical member 53 and the helical fastening portion 54 of the cylindrical member 53 is fastened to the helical portion 21 The worm gear 55 is interlocked with the worm 56 and the worm 56 is moved in the inverted state on the fixed box 51 Is connected to a drive shaft (58) of a motor (57) mounted on the slider plate.
The method according to claim 6,
The fixed box 51 is internally stationary and has a flange portion 59 at the lower side and a flange portion 59 is fixed to the horizontal portion 15 of the cutting frame 10 by bolts 60 And a cutting device for cutting the slab material.
The method according to claim 6,
The stationary box 51 is an outer stationary type and has a bracket 61 attached to a side surface thereof and a side end portion 62 of the bracket 61 fixed to a side end of the cutting frame 10 by bolts Slab material cutting device.
The method according to claim 1,
Wherein the shaft transfer device (50) is mounted on a side of the frame (10), and the connecting rod (510) of the cylinder is connected to the other end of the shaft (20).
The method according to claim 1,
Wherein the shaft transfer device (50) is engaged with a rack gear (535) connected to the other end of the shaft (20) by a pinion (530) driven by a motor.

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