KR20160027445A - Sandblast strengthening glass cuting equipment - Google Patents

Abstract

The present invention relates to a sandblast-type tempered glass cutting apparatus. In the present invention, a user can freely adjust the position of a plurality of fixed blocks constituting a nozzle unit to the position which the user wants, and each of a plurality of nozzle units automatically and accurately move to the designated position. According to the present invention, time for adjusting the position of the nozzle units is shortened by automatically moving each of the nozzle units to the position designated with respect to the size of a display device. In addition, the positions of the fixed blocks of the nozzle units are sensed by a sensing unit, thereby enabling accurate positioning of the nozzle units. Also, display devices having various sizes can be simultaneously processed by freely adjusting the position of each of the nozzle units, thereby improving productivity of products, product reliability, and increasing production efficiency. The sandblast-type tempered glass cutting apparatus comprises a nozzle unit (100) and an operating unit (200), wherein the nozzle unit includes a stationary shaft (110), a feed shaft (120), a fixed block (130), and a nozzle (140).

Description

[0001] Sandblasting strengthening glass cutting equipment [0002]

The present invention relates to a sandblast type tempered glass cutting apparatus, and more particularly, to a sandblast type tempering glass cutting apparatus which precisely converts a fixing position of a fixing block constituting a nozzle unit to a desired position by a user, Type tempered glass cutting apparatus.

In general, a tempered glass cutting apparatus, which is an air sand blasting machine for cutting the tempered glass, is a device for cutting a tempered glass such as a metal or a non-metallic material, such as an abrasive media or a grit, It is a machine that processes a workpiece.

1 to 3, a conventional sandblast type tempered glass cutting apparatus includes a main body 11, a conveyor unit 12 installed on the main body 11 and conveying the work 1, A chamber 14 which is hermetically installed at an intermediate portion of the conveyor unit 12 to process the work 1 and an abrasive 15 fixed to the nozzle 14 in the chamber 14, A plurality of nozzles 16 for jetting high pressure to the side of the workpiece 1, a Y-axis motor 13 for transferring the nozzles 16 in the Y-axis direction, A clean room 17 provided at an upper portion of the clean room 17 for spraying compressed air toward the work 1 to remove the abrasive 15 and dust, a clean room 17 for removing dust from the work 1, (18), a conveyor unit (12) provided below the center of the chamber (14) And a screw conveyor unit 20 for processing the work 1 and allowing the abrasive 15 and the dust to be returned to the hopper 19 side; A cyclone 22 connected to the pipe 21 for separating the abrasive 15 and the dust and an abrasive material 15 installed at the lower part of the cyclone 22 and separated from the dust, An abrasive storage tank 23 connected to the cyclone 22 via a second connection pipe 24 and adapted to generate a suction force according to the driving of the turbo fan 25, A collector 26 and a bag filter or cartridge 27 provided in the dust collector 26 so as to remove fine dust and to discharge only purified air to a discharge pipe (not shown) 27) containing dust separated by dust Box can be installed at one side of the portion 28 and the chamber 14 consists of a controller 29 for controlling the sequence of operation.

A conveyor unit 12 on which the workpiece 1 is placed is passed through an inlet and an outlet of the chamber 14 and an outlet of the clean room 17 so that the chamber 14 is sealed with a rubber plate (Not shown) such as a shield plate.

Accordingly, when the surface of the workpiece 1 is masked and then loaded on the conveyor unit 12, the conveyor unit 12 moves along the X-axis direction, so that the workpiece 1, which is placed on the conveyor unit 12, The abrasive 15 is continuously sprayed from a plurality of nozzles 16 provided inside the chamber 14 so that the workpiece 1 is transferred to the chamber 14 The abrasive 15 strikes the unmasked portion in the process of passing through the workpiece 1, so that the workpiece 1 is cut in the X-axis direction.

When the cutting operation in the X-axis direction is completed, the conveyance of the conveyor unit 12 is stopped and the Y-axis motor 13 provided with the nozzles 16 is driven, so that the plurality of nozzles 16 are moved in the Y- The workpiece 1 is cut with respect to the Y-axis direction.

However, the nozzle used in the conventional tempered glass cutting apparatus of the sandblast type has a fixed installation position as shown in FIG. 3, There is a problem that the size of cutting work having a size is limited.

Further, in order to adjust the cutting size, it is troublesome to replace the nozzle unit with another nozzle unit.

Alternatively, it is possible to manually change the position of the nozzle, but in this case, it is difficult to change the position of the accurate nozzle, and precise size cutting can not be secured due to the inaccuracy of the nozzle position.

Korean Registered Patent No. 861214 (registered on September 24, 2008) Korean Patent Laid-Open Publication No. 2013-14940 (Published Feb. 12, 2013) Korean Patent Publication No. 2012-15366 (2012.02.21. Open) Korean Patent Laid-Open Publication No. 2014-45509 (Published Apr. 16, 2014)

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a nozzle unit which can freely adjust a position of a plurality of fixed blocks constituting a nozzle unit to a desired position, The present invention provides a sandblast type tempered glass cutting apparatus which is moved.

In order to accomplish the object of the present invention as described above, the sandblast type tempered glass cutting apparatus according to the present invention is provided with an abrasive blast furnace, which is formed inside a chamber and which is provided with a workpiece conveyed to a chamber through a conveyor unit, A nozzle unit for cutting the workpiece in the X-axis or Y-axis direction, and a drive unit for providing a driving force to move the nozzle unit in the X-axis or Y-axis direction, The nozzle unit comprising: a fixed shaft; A conveying shaft that is spaced apart from the fixed shaft by a predetermined distance and provides a conveying force to be reciprocated by a predetermined distance; A fixed block that is selectively fixed between the fixed shaft and the feed shaft and in which the fixed position of the fixed shaft is changed by the reciprocating feed force of the feed shaft; And a nozzle disposed on one side of the fixed block for spraying the abrasive to cut the work while changing the size of the work in the X or Y axis direction according to the fixed position converted by the feed axis. do.

In the sandblast type tempered glass cutting apparatus according to the present invention, the driving unit may include: a motor; A first guide shaft fixed to an extension shaft of the motor; A second guide shaft spaced apart from the first guide shaft by a predetermined distance; The first and second guide shafts are disposed on the first and second guide shafts. The first and second guide shafts are supported by the first and second guide shafts, respectively, And a protection tube for preventing the tube from being damaged.

In the tempered glass cutting apparatus of the sandblast type according to the present invention, the tempered glass cutting apparatus of the air sand blast type further includes an origin sensor for sensing the fixing position of the fixed block to be precisely converted .

In the sandblasted tempered glass cutting apparatus according to the present invention, the origin sensor is configured to sense an initial position of each of a plurality of fixed blocks constituting the fixed shaft.

In the sandblasted tempered glass cutting apparatus according to the present invention, the feed shaft is provided with a motor for providing forward and reverse rotational force; A ball screw for converting a rotational force of the motor into a reciprocating feed force; And a conveying block which is formed at one side of the ball screw and is fixed to the other side of the conveying shaft so that the conveying shaft is conveyed by a reciprocating sliding along the reciprocating conveyance of the ball screw to convey the conveying shaft by a predetermined distance.

In the sandblast type tempered glass cutting apparatus according to the present invention, the nozzle unit may further include a nozzle rotation motor for providing rotational force to change the fixing angle of the nozzle.

In the sandblast type tempered glass cutting apparatus according to the present invention, the fixed block includes a cylinder block having nozzles formed on one side thereof; A second block which is disposed on one side of the transporting shaft and presses the transporting shaft together with the second block so that the cylinder block is transported along the transporting distance of the transporting shaft And a third block.

In the sandblast type tempered glass cutting apparatus according to the present invention, when the second block is brought into close contact with the fixed shaft, the fixed block is held firmly in close contact with the fixed block so that the cylinder block And a first block for firmly holding the first block.

According to the present invention, the position adjustment time of the nozzle is shortened by automatically moving each of the plurality of nozzle units to a predetermined position corresponding to the size of the display, and the fixed block position of the nozzle unit is sensed by the sensor unit, , It is possible to simultaneously process various sizes of displays by freely adjusting the position of each of the plurality of nozzle units. Accordingly, it is possible to improve the productivity of the product, increase the production yield, and improve the reliability of the product.

In addition, a protection tube is formed on the first and second guide shafts of the driving portion to prevent foreign matter such as dust, which is generated when cutting the tempered glass, from penetrating the first and second guide shafts, .

1 is a schematic perspective view of a conventional tempered glass cutting apparatus of the sand blast type.
2 is a schematic cross-sectional view of a conventional tempered glass cutting apparatus of the sand blast type.
3 is a schematic front view of a state in which a nozzle is installed in a conventional chamber.
4 is a schematic view showing a coupling relation between a nozzle unit and a driving unit according to the present invention.
Fig. 5 is a schematic front view showing a coupling relationship of the nozzle unit according to the present invention; Fig.
FIG. 6 is a schematic side view showing a coupling relationship of the nozzle unit according to the present invention. FIG.
7 is a schematic configuration diagram of a fixed block according to the present invention;
8 is a view showing the operating relationship of the fixed block according to the present invention,
8a is a state in which the fixed block is fixed to the fixed shaft, and 8b is a state in which the fixed block is fixed to the conveying shaft.
Fig. 9 is a schematic view showing a coupling relationship of the nozzle unit according to the present invention,
9a is a state in which the fixed block is fixed to the fixed shaft, and 9b is a state in which the fixed block is moved a predetermined distance along the transport axis.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings (the same reference numerals are used for the same components as the conventional ones, and a detailed description thereof will be omitted).

A sandblast type tempered glass cutting apparatus according to the present invention comprises a main body 11, a conveyor unit 12 for conveying the workpiece 1 to the main body 11, A nozzle 14 installed in the chamber 14 for cutting the work 1 in the X-axis and Y-axis directions, and a nozzle 14 disposed in the chamber 14 for cutting the work 1, A sensor unit for sensing a position of a nozzle included in the nozzle unit to change the position of the nozzle unit, and a sensor unit disposed on one side of the chamber, And a clean room 17 for removing the clean room 17.

4 to 7, the nozzle unit 100 cuts the workpiece 1 in the X-axis or Y-axis direction while being transported by the driving force provided by the driving unit 200. As shown in FIG.

The nozzle unit 100 includes a fixed shaft 110 that is formed in the driving unit 200 and is transported in the X axis direction or the Y axis direction of the work 1 by a driving force and a fixed shaft 110 that is spaced apart from the fixed shaft 110 A fixed block 130 fixed to the fixed shaft 110 and optionally fixed to the transport shaft 120 to convert the fixed position of the fixed shaft 110, And a nozzle 140 for cutting the work 1 through an abrasive material provided on the fixed block 130. [

The fixed shaft 110 is fixed to the conveying block 130 at a predetermined interval so that the conveying block 130 is moved in the X or Y axis direction of the work 1 by the driving force of the driving unit 200 .

The feed shaft 120 is spaced apart from the fixed shaft 110 and fixed to the fixed shaft 110 while being reciprocated by a predetermined length along the longitudinal direction of the fixed shaft 110 130).

5 and 6, the conveying shaft 120 includes a motor 122, a ball screw 124 for converting the forward and reverse rotational force provided by the motor 122 into a reciprocating feed force, And a transport block 120 fixed to one side of the ball screw 124 and fixed to the other side of the transport block 120 to reciprocate and slide the transport axis 120 according to the reciprocating force of the ball screw 124. [ 126).

The conveying shaft 120 is not limited to a ball screw type which is conveyed by a rotational force of a motor for a predetermined length and can be any means that can be reciprocated by a certain length using a motor or fluid pressure .

The fixed block 130 is fixed to one side of the nozzle 140 and is fixed to the fixed shaft 110. The fixed block 130 may be fixed to the fixed shaft 110 by the reciprocating feed force of the feed shaft 120, 110 are changed so that the fixed position of the nozzle 140 is converted.

7 and 8, the fixed block 130 includes a block cylinder 132 in which the nozzle 140 is formed, and a block cylinder 132 having one side of the fixed shaft 110, A second block 136 selectively disposed between the fixed shaft 110 and the feed shaft 120 and a second block 136 formed on one side of the feed shaft 120, And a third block 138 that presses the transfer shaft 120 together with the second block 138.

The first to third blocks 134, 136, and 138 may have a rectangular parallelepiped shape as shown in FIGS. 7 to 8. However, the first to third blocks 134, 136, and 138 may be formed in a roll shape. In this case, a semicircular shape identical to the cross sectional area of the fixed shaft 110 and the feed shaft 120 is formed on the outer circumferential edge to enlarge the contact area with the fixed shaft 110 and the feed shaft 120.

In other words, the first block 134 is formed with semicircular grooves at one end to maintain a close contact state with one surface of the fixed shaft 110, and the second block 136 has the fixed shaft 110 and the feed A semicircular groove is formed on one surface of the shaft 120 to facilitate adhesion. A semicircular groove is formed on the third block 138 at one end to selectively contact the transport shaft 120.

8A, when the first block 134 and the second block 136 are brought into close contact with each other at both ends of the fixed shaft 110, the third block 136 is separated from the transfer shaft 120 by a predetermined distance The fixed block 130 remains fixed to the fixed shaft 110 even if the conveying shaft 120 is conveyed.

8B, when the second block 136 is separated from the fixed shaft 110 and the second and third blocks 136 and 138 are brought into close contact with both ends of the transfer shaft 120, The fixing block 130 is transferred by the conveyance of the conveying shaft 120.

5 to 6, the nozzle unit 100 includes a nozzle rotation motor 150 that provides a rotational force to maintain the nozzle 140 at a predetermined angle. The nozzle rotation motor 150 changes the angle of the nozzle 130 within a predetermined range.

4, the driving unit 200 includes a motor 210, a first guide shaft 220 fixed to an extension shaft of the motor 210, a first guide shaft 220, A second guide shaft 230 configured to be spaced apart from the first guide shaft 220 by a predetermined distance and a protective tube 240 formed on the first and second guide shafts 220 and 230 to prevent damage by abrasive or dust .

The motor 210 is preferably constituted by a servo motor capable of precise control.

It is preferable that the first and second guide shafts 220 and 230 are LM guides that can be precisely transported. Of course, the present invention is not limited thereto, and any structure can be used as long as it can stably feed the nozzle unit 100 along the X-axis or Y-axis direction.

The protective pipe 240 is formed on the first and second guide shafts 220 and 230 and is supported by the nozzle unit 100 for conveying along the first and second guide shafts 220 and 230 Is a means for covering the workpiece 1 so as to prevent the workpiece 1 from being damaged by the abrasive or dust generated by the cutting process. In this case, it is preferable that the protective pipe 240 is a corrugated pipe which is flexible in length. In addition, the protective pipe 240 is preferably formed of soft rubber, silicone, or synthetic resin.

The nozzle unit 100 includes an origin sensor 300 which is formed in the nozzle unit 100 and senses the fixing position of the fixing block 130 of the nozzle unit 100 so as to be precisely controlled .

9, the origin sensor 300 includes a plurality of fixed blocks 130 fixed to the fixed shaft 110, a fixed block 130 fixed to the first fixed shaft 110, In the direction of the arrow.

The state of conversion of the fixing position of the nozzle unit of the sandblast type tempered glass cutting apparatus constructed as described above will be described below.

First, as shown in FIG. 9A, each fixed block 130 formed on the fixed shaft 110 maintains the origin of the fixed position by the origin sensor 300.

8B, the first block 134 and the second block 136, which are in close contact with the fixed shaft 110, are moved in the second direction, The second block 136 and the third block 138 are pressed against the transfer shaft 120 formed on one side of the fixed shaft 110 while the block 136 releases the pressing. The second and third blocks 136 and 138 have an operating relationship with each other. For example, when the transfer shaft 120 is pressed against the second and third blocks 136 and 138, And the second and third blocks 136 and 138 have mutual operating relationships to release the pressing of the conveying shaft 120. [ At this time, the second block 136 presses one side of the fixed shaft 110 when the third block 138 is in a widening operation relationship. The second block 136 selectively reciprocates between the first block 134 and the third block 138 to selectively push the fixed shaft 110 or the feed shaft 120 to fix the fixed block 130 The position is selected.

The conveying block 126 is conveyed along the ball screw 124 by the conveying force of the motor 122 constituted on one side of the conveying shaft 120 so that the conveying block 126 is conveyed The shaft 120 is transported a certain distance.

Therefore, as the transport shaft 120 is transported by the transport block 126 by a predetermined length, the stationary block 130, which keeps the second and third blocks 136 and 138 in a state of being pressed against each other, (120).

When the feeding of the feed shaft 120 is completed, the second and third blocks 136 and 138 are released from the pressing force and the second block 136 is pressed against the fixed shaft 110 The fixed block 130 is fixed to the fixed shaft 110 by the mutual pressing force of the first and second blocks 134 and 136 on the fixed shaft 110. [

When the fixed position is to be changed at the current position of the fixed block 130, the pressing force of the first and second blocks 134 and 136 of the fixed block 130 is released. At the same time, 2 and the third blocks 136, 138 are fixed to the transfer shaft 120 as they are pressed together.

The conveying shaft 120 conveys the fixing block 130 to the initial position, that is, the position where the origin sensor 300 configured on the fixing shaft 110 is configured. When the fixing block 130 is moved to the fixing shaft 110, And then the position of the fixed block 130 is initialized.

The fixed block 130 positioned on the fixed shaft 110 is transferred to the transport shaft 120 in the manner described above and the transport block 120 is moved to transport the fixed block 130 at a new transport distance .

In another example, the origin sensor has one origin sensor at one end of the nozzle unit 100. [

In this case, when the fixed position of the fixed block 130 is to be changed, the fixed block 130 formed on the fixed shaft 110 is transferred to the transfer shaft 120 in the above-described manner.

At this time, the conveying shaft 120 is moved to the position where the origin sensor is located, and the position of the fixing block 130 is initialized by the sensing of the origin sensor, When the transfer shaft 120 is positioned, the fixing block 130 is transferred to the conversion position.

After the fixed block 130 fixed on the fixed shaft 110 is mounted on the conveying shaft 120, the conveying shaft 120 is moved to the home position And the fixing block 130 is moved to the side of the fixing block 130 side.

When the origin sensor is sensed by the fixing block 130, the position of the fixing block 130 is initialized. Thereafter, as the feeding shaft 120 is moved by a new conversion distance, .

As described above, the fixed block having the nozzle formed between the fixed shaft and the transport shaft can be formed, and the tempered glass can be freely cut to a size desired by the user as the fixed block is transported by the transport distance of the transport shaft.

The above description is only one embodiment for carrying out the tempered glass cutting apparatus of the sand blast type, and the present invention is not limited to the above-described embodiment. It will be understood by those skilled in the art that various changes may be made without departing from the spirit of the invention.

100: nozzle unit 110: fixed shaft
120: Feed shaft 130: Fixed block
132: block cylinder 134: first block
136: second block 136: third block
140: nozzle 150: nozzle rotation motor
200: driving unit 210: motor
220: first guide shaft 230: second guide shaft
240: Protection tube 300: Home sensor

Claims (8)

A nozzle unit formed inside the chamber for spraying an abrasive material supplied from the outside to a workpiece transferred to the chamber through a conveyor unit to cut the workpiece in the X or Y axis direction; And a driving unit for supplying a driving force to be fed in the Y-axis direction,
The nozzle unit 100 includes a fixed shaft 110;
A feed shaft 120 spaced apart from the fixed shaft 110 by a predetermined distance and providing a feed force to be reciprocated by a predetermined distance;
A fixed block 130 selectively fixed between the fixed shaft 110 and the feed shaft 120 and adapted to change the fixed position of the fixed shaft 110 by a reciprocating feed force of the feed shaft 120; And
The abrasive is sprayed to cut the work piece 1 while changing the size of the work piece 1 in the X axis direction or the Y axis direction depending on the fixed position converted by the feed axis 120 A nozzle 140;
Wherein the glass-reinforced glass is a glass-reinforced glass. The driving unit according to claim 1,
A motor 210;
A first guide shaft 220 fixed to an extension shaft of the motor 210;
A second guide shaft 230 spaced apart from the first guide shaft 220 by a predetermined distance; And
The fixing block 130 is formed on each of the first and second guide shafts 220 and 230 and is moved along the first and second guide shafts 220 and 230 to cut the workpiece 1 A protective pipe 240 for preventing the first and second guide shafts 220 and 230 from being damaged by the abrasive or dust generated during the machining;
Wherein the glass-reinforced glass is a glass-reinforced glass. The method according to claim 1,
In the air-sandblast type tempered glass cutting apparatus,
Further comprising an origin sensor (300) for sensing the fixing position of the fixing block (130) to be precisely converted. The method of claim 3,
Wherein the origin sensor (300) is configured to sense an initial position of each of the plurality of fixing blocks (130) formed on the fixed shaft (110). The method according to any one of claims 1 to 4,
On the conveying shaft 120,
A motor 122 for providing positive and reverse torque;
A ball screw 124 for converting the rotational force of the motor 122 into a reciprocating feed force; And
The conveying shaft 120 is fixed to the other side of the ball screw 124 and reciprocally slid along the ball screw 124 so as to feed the conveying shaft 120 a predetermined distance Block 126;
Wherein the glass-reinforced glass is a glass-reinforced glass. The method according to any one of claims 1 to 4,
In the nozzle unit 100,
Further comprising a nozzle rotation motor (150) for providing a rotational force to change the fixed angle of the nozzle (140). The method according to any one of claims 1 to 4,
The fixing block 130 includes:
A cylinder block 132 in which a nozzle 140 is formed at one side;
A second block 136 selectively in close contact with the fixed shaft 110 and the feed shaft 120;
The second block 136 is formed on one side of the transport shaft 120 so that the transport block 120 is pressed with the second block 136 so that the cylinder block 132 is transported along the transport distance And a third block (138) for cutting the glass substrate (130). The method of claim 7,
In the fixed block 130,
When the second block 136 is in close contact with the fixed shaft 110, the second block 136 is firmly held in close contact with the fixed block 110 to support the cylinder block 132 firmly fixed to the fixed shaft 110 And a first block (134) disposed between the first block (134) and the second block (134).

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