KR20110029522A - Device for cutting side and edge of thin plate glass synchronously and assembly for manufacturing thin plate glass using the same - Google Patents

Abstract

The integrated sheet glass processing apparatus includes a body portion, a head portion moving along one surface of the body portion and provided with a chamfering cutter and a chamfering cutter, a glass block handler moving in a direction perpendicular to the moving direction of the head portion and fixing the glass block. And a changer for selectively exchanging the chamfering cutter and the chamfering cutter. The processing assembly using the integrated sheet glass processing apparatus includes a plurality of integrated sheet glass processing apparatuses, an input / output plate on which the glass blocks are carried in and out, and a transfer unit for transferring the glass blocks. According to the integrated sheet glass processing apparatus and the processing assembly using the same, the chamfering process and the chamfering process can be performed in one apparatus using the changer provided in the processing apparatus, thereby increasing the work efficiency and chamfering the glass block. By chamfering at the same time using the cutter has the advantage that the working speed is improved.

Description

Integrated sheet glass processing device and processing assembly using same {DEVICE FOR CUTTING SIDE AND EDGE OF THIN PLATE GLASS SYNCHRONOUSLY AND ASSEMBLY FOR MANUFACTURING THIN PLATE GLASS USING THE SAME}

The present invention relates to an integrated thin glass processing apparatus and a processing assembly using the same, and more particularly, to a processing apparatus and an assembly for processing a glass block laminated laminated glass used as tempered glass of electronic products.

Recently, due to the demand for slimming of electronic products such as mobile phones, conventional glass or acrylic, which is conventionally used, is replaced by tempered thin glass. Such tempered thin glass is used as a display window of portable electronic products such as mobile phones, PMP, MP3, the thinner the tempered thin glass can occupy an excellent position in design and portability.

In order to manufacture such tempered thin glass, the flat glass of the large flat plate must be cut to a certain size, and then cut to fit the size of the electronic product through a chamfering and chamfering process. However, since the thin glass itself is very thin, there is a risk of breakage during the process of chamfering and chamfering, and individually chamfering and chamfering the thin glass causes a lot of loss in manpower and time.

In order to solve this problem, a method of integrally processing after laminating laminated glass by a wet method has been proposed. In the laminated bonding method, the bonding material is coated on the thin glass by dissolving the bonding material in a water tank in order to process the thin glass of the thin film, and then immersing the thin glass in the bonding material. Then, after the laminated glass coated with the bonding material is laminated in several layers, heat is applied to the laminated glass to bond the plurality of laminated glass.

Since the laminated glass bonded by the bonding material is formed in the same shape as the glass block, the sheet glass is cut to a predetermined size using a general-purpose milling, and then the cut sheet glass is integrally processed through a faceting process. The chamfering process means a process of grinding and uniformizing a state where the side of the thin glass is not uniform by cutting.

When the chamfering process is completed, a chamfering process for cutting the edges to the thin glass is carried out. Chamfering process is a kind of chamfering work for thin glass.

Figure 1 shows a chamfering step of the laminated bonding method according to the prior art. As shown, a fine layer of laminated material 3 is formed between the plurality of thin glass glasses 1. Since the gap between the thin glass (1) is fine, it is not possible to chamfer the glass block state. That is, due to the thickness of the cutting blade of the chamfering device used in the chamfering device it is not possible to cut between the gap between the thin glass (1).

Therefore, after separating the glass block into the individual laminated glass (1) as shown, the chamfering work must be performed separately. The chamfering process is completed by cutting the edges of each of the thin glass glasses 1, and after the chamfering process, the bonding material layer 3 is removed.

However, since the chamfering work and the chamfering work must be provided with a separate device, a plurality of processing devices required for thin glass processing are required, and thus there is a problem that the processing time increases.

In addition, the individual chamfering work is required to cut the thin glass respectively, so the processing time required for chamfering work increases, and in the process of chamfering the thin glass individually, a lot of defective products are generated due to the lack of rigidity of the thin glass itself.

The present invention is to solve such a conventional problem, it is an object of the present invention to provide a processing apparatus capable of simultaneously cutting and chamfering.

Another object of the present invention is to provide a processing apparatus capable of chamfering a glass block integrally.

According to a feature of the present invention for achieving the above object, the integrated sheet glass processing apparatus of the present invention is a device for processing a glass block integrally laminated bonding by inserting a spacer between the thin glass, the body portion; A head portion connected to the head support provided in the body portion to be movable, and optionally including a chamfering cutter for chamfering the glass block and a chamfering cutter for chamfering the glass block; A glass block handler which is connected to the body to be movable in a direction perpendicular to the moving direction of the head, and fixes the glass block; and a changer for selectively exchanging the chamfering cutter and the chamfering cutter provided in the head part. It is preferable to include.

The glass block handler of the present invention preferably includes a cover for preventing scattering of debris generated during the processing of the glass block.

The glass block handler of the present invention includes a work table reciprocating along the upper surface of the body portion, the cover is preferably rotatably connected to the work table.

The cover of the present invention preferably opens only one side, and the head portion correspondingly rotates to chamfer or chamfer the glass block through the opened one side.

The glass block handler of the present invention includes a support frame rotatably connected to an upper surface of the work table and a pressing frame spaced apart from the supporting frame at a predetermined interval, and the pressing frame is pressed in the direction of the supporting frame to support the supporting frame. It is preferable to fix the glass block located between the frame and the pressing frame.

Pressing frame of the present invention is the upper frame; It is preferable that the lower frame is configured to be movable downward from the upper frame; and a pressurized cylinder provided between the upper frame and the lower frame, and expands or contracts by a fluid supplied from the outside.

The chamfering cutter of the present invention is preferably composed of a negative chamfering cutter or a hole chamfering cutter.

The changer of the present invention is a support block provided on the upper surface of the body portion; A rotating part rotatably provided on an upper surface of the support block; It is preferable to include a turntable connected to the rotating part, the chamfering cutter and the chamfering cutter is fixed.

The turntable of the present invention is formed of a cross-shaped plate, and both sides open in opposite directions to each other includes a removable groove for fixing the chamfering cutter and the chamfering cutter and a cutter support on which the chamfering cutter and the chamfering cutter is seated. It is desirable to.

The changer of the present invention is preferably provided inside the head portion.

The processing assembly using the integrated sheet glass processing apparatus of the present invention comprises a plurality of integrated sheet glass processing apparatuses; It is preferable to include a transport unit for transferring the glass block on which the glass block is seated; and the glass block to the input and export surface plate or the integrated sheet glass processing apparatus.

It is preferable that the input / output table of the present invention includes a plurality of seating parts on which the glass blocks are seated.

The transfer unit of the present invention is configured to be movable along the connection rail, it is preferably composed of a multi-joint robot having a hand grip portion for holding the glass block.

It is preferable that the integrated thin sheet glass processing apparatus of this invention is provided with six pieces.

According to the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention, by using the changer provided in the processing device by replacing the surface cutter and the chamfering cutter to perform the chamfering process and chamfering process in one device Since the work efficiency can be increased, and the glass blocks in which the spacers are inserted between the sheet glass are chamfered at the same time by using the chamfering cutter, there is an advantage that the working speed is improved compared to the conventional chamfering work performed individually.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention will be described in more detail.

2 to 8 show a preferred embodiment of the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention.

Glass blocks processed by the thin glass processing apparatus according to the present invention are bonded by a lamination bonding method using a spacer. In the laminated bonding method using a spacer, as shown in FIG. 2, the bonding material 10 is coated on the upper surface of the lower base, and a sheet of thin glass 13 is laminated on the bonding material 10. Then, after the bonding material 10 is applied to the laminated thin glass 13 upper surface, the spacer 15 is laminated on the upper surface. In this way, several sheets of laminated glass 13 are laminated.

The spacers 15 are inserted between the thin glass glasses 13 to form gaps between the thin glass glasses 13 to chamfer the glass blocks. The spacer 15 may be made of a material such as PP, PE, PET, ABS, Teflon, and a material that can maintain a constant gap between the thin glass 13, such as cotton yarn, iron and aluminum. The glass block constituted as described above is processed by the thin glass processing apparatus according to the present invention.

3 shows a processing assembly using the integrated sheet glass processing apparatus according to the present invention.

As shown, the processing assembly of the present invention includes an entry and exit plate 20 and an export plate 30 for carrying in and out of a glass block including a spacer. In addition, a plurality of seating parts 23 on which the glass blocks are seated are provided on the upper surfaces of the entry / exit surface plate 20 and the export surface plate 30.

A connection rail 40 is provided between the entry and exit plate 20 and the transfer plate 30. In addition, the connection rail 40 is seated and moves the transfer unit 50 for moving the glass block seated on the entry and exit plate 20 to the integrated processing device 60 or the take-out surface 30 to be described below. .

The transfer unit 50 may be composed of a plurality of joints and a robot having a hand grip part for holding a glass block, the glass block seated on the seating portion 13 of the upper surface of the entry and exit plate 20. The gripper may be transferred to the integrated processing apparatus 60 or the glass block seated on the integrated processing apparatus 60 may be mounted on the unloading surface 30.

Both sides of the connection rail 40 is provided with a plurality of integrated processing device 60 for chamfering or chamfering the glass block. The integrated machining apparatus 60 may vary in number depending on the processing speed and the performance of the transfer unit 50.

4, the integrated processing apparatus 60 is shown. As shown, the integrated processing apparatus 60 includes a body portion 61 positioned within a range in which the transfer unit 50 can transport the glass block. The upper surface of the body portion 61 is provided with a head support (63) having a head portion 70 that moves along the connecting rail 40 direction (hereinafter referred to as the 'X-axis direction').

The head 70 provided in the head support 63 is driven by a driving motor (not shown), and is composed of a ball screw, a ball spline, or the like. It is configured to be movable in the X-axis direction by screwing the guide bar 65 provided in the 63.

The head part 70 may be provided with a chamfering cutter 71 for uniformly processing the side of the glass block or a chamfering cutter 73 for chamfering by cutting the edge of the thin glass. The chamfering cutter 71 and the chamfering cutter 73 are fixed by a chuck (not shown) provided in the head portion 70.

In addition, the cutter mounted on the head part 70 may be equipped with a negative machining (-R) chamfering cutter or a hole machining chamfering cutter.

5 shows a planar cutter 71 for uniformly processing the side of the glass block. As shown in the drawing, the side surface of the glass block can be uniformly processed while the surface cutter 71 formed in a drum shape having a groove 71a formed in a diagonal direction on one side thereof rotates at a high speed.

6 shows a chamfering cutter 73 for cutting and chamfering the edges of the thin glass. As shown in the drawing, a plurality of uneven portions 73a protruding in the longitudinal direction on one side are drawn between the spacers 15 inserted between the glass blocks and rotated at a high speed to chamfer the glass blocks integrally.

In addition, the cutters 71 and 73 are configured to move along a vertical direction (hereinafter, referred to as 'Z axis direction') on the upper surface of the body portion 61. That is, the cutters 71 and 73 may be configured to move in the Z-axis direction by screwing the head portion 70 or screwing the rack and pinion.

The chamfering cutter 71 and the chamfering cutter 73 are configured to be detachable from the head portion 70. The upper surface of the body portion 61 is provided with a changer 80 for detaching and replacing the chamfering cutter 71 and the chamfering cutter 73 from the head portion 70.

7 shows a changer 80 for replacing the chamfering cutter 71 and the chamfering cutter 73. The changer 80 includes a support block 81 provided on an upper surface of the body portion 61, and a rotation unit 83 rotatably provided on an upper surface of the support block 81.

The turntable 85 for replacing the chamfering cutter 71 and the chamfering cutter 73 is provided on the upper surface of the rotating part 83. The turntable 85 may be formed of a cruciform plate as shown in FIG. 7, and one side of the cruciform plate in one longitudinal direction may be opened in the opposite direction to fix the cutters 71 and 73. Removable grooves 87 are formed respectively.

In addition, the plate support of the turntable 85 in the other longitudinal direction is provided with a cutter support 88 for mounting the cutter. The cutter seated on the cutter support 88 is selectively mounted to the head portion 70.

Therefore, the cutters 71 and 73 fixed to the head part 70 are inserted into and separated from the detachable groove 87 formed in the turntable 85, and the turntable 85 rotates to turn the 85. The cutters 71 and 73 provided on the cutter support 88 of the cutter 70 may be interchanged with each other by being mounted to the head part 70.

The upper surface of the body portion 61 is provided with a work table 90 on which the glass block to be transported by the transfer unit 50 is seated. The work table 90 is provided on the upper surface of the body portion 61 and moves in the Y-axis direction along a guide rail 91 formed of a component such as an LM guide.

The upper surface of the work table 90 is provided with a glass block handler 100 for holding the glass block to prevent debris from splashing when chamfering and chamfering. As shown in FIG. 8, the glass block handler 100 for holding the glass block is rotatable on the upper surface of the work table 90.

The glass block handler 100 includes a support frame 101 rotatably connected to a rotating boss 93 provided on an upper surface of the work table 90. The support frame 101 is configured to be rotatable by being connected to a rotating gear (not shown) provided inside the rotating boss 93.

In addition, the support drum 103 provided at the center of the support frame 101 is configured to be fixed to the work table 90. Therefore, the support frame 101 rotates with respect to the rotary boss 93 and the support drum 103, but the rotary boss 93 is fixed to the support drum 103 and does not rotate. In addition, the upper surface of the support drum 103 is provided with a fixed bearing 105 for fixing the lower surface of the glass block.

Both ends of the support frame 101 are provided with support bars 107 formed in the vertical direction. In addition, the support bar 107 is provided with a pressing frame 110 for fixing the upper surface of the glass block.

The pressing frame 110 is composed of an upper frame 111 and a lower frame 113. The upper frame 111 is fixed to the support bar 107, the lower frame 113 is movable up and down along the support bar 107.

A pressurizing cylinder 115 is provided between both ends of the upper frame 111 and the lower frame 113. The pressure cylinder 115 may secure the upper surface of the glass block located below the lower frame 113 by expanding the lower frame 113 downward by expanding by the air or fluid flowing from the outside. have.

In addition, a fixed bearing 105 is provided at a portion of the lower frame 113 that faces the fixed bearing 105 provided on the upper surface of the support drum 113. Therefore, a glass block is seated and fixed between the fixed bearing 105 provided in the support drum 113 and the fixed bearing 105 provided in the lower frame 113.

The support frame 101 and the pressing frame 110 is provided with a cover 117 formed to open only one side. The cover 117 serves to prevent debris from scattering around in the process of chamfering or chamfering the glass block. The cover 117 may be further provided with a confirmation window 119 to confirm the processing state.

Hereinafter will be described in detail the action of the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention having the configuration as described above.

First, the glass block including the spacer is seated on the seating portion 23 of the entry and exit plate 20. Then, the transfer unit 50 grips the glass block seated on the seating portion 23 and transfers it to the integrated processing apparatus 60 provided at a predetermined position.

As shown in FIG. 9, the transfer unit 50 moves along the connection rail 40 to the integrated processing apparatus 60, and then supports the gripped glass block of the glass block handler 100. It is positioned between the fixed bearing 105 provided in 103 and the fixed bearing 105 provided in the lower frame 113.

Then, by pushing the lower frame 113 downward while the pressure cylinder 115 of the pressure frame 110 is expanded, it is possible to firmly fix the glass blocks located between the fixed bearing 105.

As described above, when the glass block is fixed to the glass block handler 100, the glass block handler 100 is rotated 180 ° as shown in FIG. 10, and then along the guide rail 91 of the body portion 61. The head support 63 moves to the position provided. At this time, the pressing frame 110, the support frame 101 and the cover 117 of the glass block handler 100 is integrally rotated, but the glass block fixed between the fixed bearing 105 does not rotate.

When the glass block handler 100 is moved, the surface finishing process for uniformly processing the side of the glass block is performed first. The cutter used for the roughing operation is the face cutting cutter 71 shown in FIG.

The chamfering operation starts with the operation of grinding the side of the glass block uniformly while the head portion 70 provided in the head portion support 63 reciprocates along the head portion support 63 in the X-axis direction. In this case, since the cover 117 of the glass block handler 100 covers all directions except the direction of the head part 70, debris generated during the surface grinding may be prevented from scattering to the periphery.

When the finishing processing for one side of the glass block by the head unit 70 is completed, the glass block handler 100 is rotated 90 ° as shown in FIG. At this time, the glass blocks fixed between the fixed bearings 105 do not rotate.

In addition, the work table 90 provided with the glass block handler 100 is Y along the guide rail 91 in the state in which only the face cutter 71 is rotated at a high speed while the head portion 70 is not moved. The face is cut while reciprocating in the axial direction. At this time, the cover 117 can prevent the debris from scattering around.

When the grinding is finished by the movement of the work table 90, the glass block handler 100 is rotated 90 degrees again, and the head portion 70 is reciprocated while reciprocating in the X-axis direction.

Then, the glass block handler 100 is rotated 90 ° and the work table 90 is grinded while reciprocating in the Y-axis direction so that all sides of the glass block can be faced.

When the chamfering process is completed by such a method, the chamfering cutter 71 is replaced with the chamfering cutter 73, and then the chamfering process is performed.

As shown in FIG. 14, the head portion 70 moves to the upper surface of the changer 80 provided on the upper surface of the body portion 61. Then, the surface-mounted cutter 87 fixed to the head part 70 is inserted into the detachable groove 87 formed in the turntable 85 of the changer 80.

In addition, the head part 70 releases the chuck to separate the planing cutter 71 and fixes it to a detachable groove 87 formed at one end of the turntable 85, and the turntable 85 rotates to The chamfering cutter 73 prepared in the cutter support 88 formed at the other end of the turntable 85 is replaced.

When the turntable 85 rotates so that the chamfering cutter 73 is positioned below the head portion 70, the head portion 70 is coupled to the chamfering cutter 73 by fixing the chuck. By such a method, the chamfering cutter 71 and the chamfering cutter 73 are continuously exchanged, and it can advance alternately a chamfering process and a chamfering process.

In addition, in order to mount the negative machining (-R) chamfering cutter or the hole machining chamfering cutter on the head portion 70, the negative machining (-R) chamfering cutter or the hole chamfering cutter on the turntable 85 Can be replaced.

When the chamfering cutter 73 is coupled to the head part 70, the glass block handler 100 is continuously rotated by the above-mentioned method, and the chamfering operation is performed. The chamfering operation can chamfer the thin glass by digging the spacer 15 between the thin glass while the uneven portion 73a of the chamfering cutter 73 rotates at high speed. When the chamfering operation is completed, the upper edge and the lower edge of the thin glass as shown in Figure 16 is cut at a predetermined angle.

In addition, when a negative machining (-R) chamfering cutter or a hole chamfering cutter is mounted on the head part 70, the corners of the negative machining part and the hole part are also cut at a predetermined angle.

When the chamfering and chamfering operation for the glass block is finished as described above, the work table 90 moves forward, and the transfer unit 50 grips the glass block. Then, the pressing cylinder 115 of the glass block handler 100 is reduced so that the lower frame 113 moves upward to release the fixing of the glass block.

The transfer unit 50 ends the processing process by seating the gripped glass block on the upper surface of the export surface plate (30).

The transfer unit 50 transfers the glass blocks to the plurality of integrated processing devices 60 or the glass blocks processed by the integrated processing device 60 according to the work order to the carrying out table 30. It can be programmed to run continuously.

In the scope of the basic technical spirit of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the claims which will be described later. .

For example, the chamfering cutter and the chamfering cutter provided in the head of the present invention may be replaced by the chamfering cutter and the chamfering cutter by the changer provided in the head itself. That is, both the chamfering cutter and the chamfering cutter are mounted inside the head, and the chamfering cutter and the chamfering cutter can be automatically replaced inside the head by a changer designed to be mounted inside the head.

According to the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention as described in detail above has the following advantages.

By replacing and mounting the chamfering cutter and chamfering cutter using a changer provided in the processing apparatus, the chamfering process and the chamfering process can be performed in one apparatus, thereby increasing the work efficiency.

By chamfering the glass block in which the spacers are inserted between the thin glass using the chamfering cutter at once, there is an advantage in that the working speed is improved as compared to the conventional chamfering work performed individually.

1 is a process state showing a process of chamfering a thin glass block according to the prior art.

Figure 2 is an exploded perspective view showing a structure of a glass block used in the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention.

Figure 3 is a perspective view showing a preferred embodiment of the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention.

Figure 4 is a perspective view showing an integrated sheet glass processing apparatus according to the present invention.

5 is a perspective view showing a surface cutter of the integrated sheet glass processing apparatus according to the present invention.

Figure 6 is a perspective view of the chamfering cutter of the integrated sheet glass processing apparatus according to the present invention.

Figure 7 is a partial perspective view showing a changer of the integrated sheet glass processing apparatus according to the present invention.

Figure 8 is a partial perspective view showing a glass block handler of the integrated sheet glass processing apparatus according to the present invention.

9 to 15 is a process state diagram showing the state of stepping and chamfering the glass block by the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention.

Figure 16 is a perspective view showing a processing state of the glass block processed by the integrated sheet glass processing apparatus and the processing assembly using the same according to the present invention.

Description of the Related Art [0002]

13: thin glass 15: spacer

20: Entry and exit desk 30: Entry and exit board

40: connecting rail 50: transfer unit

60: integrated machining device 61: body portion

63: head portion support 70: head portion

71: cutting cutter 73: chamfering cutter

80: Changer 85: Turntable

90: work table 100: glass block handler

101: support frame 110: pressure frame

115: pressure cylinder 117: cover

Claims (14)

An apparatus for processing a glass block in which a spacer is inserted between thin glass sheets to be integrally laminated and laminated. Body portion; A head portion which is connected to be movable along a head supporter provided in the body portion, and optionally includes a chamfering cutter for chamfering the glass block and a chamfering cutter for chamfering the glass block; A glass block handler connected to the body part to be movable in a direction perpendicular to the moving direction of the head part and fixing the glass block; and And a changer for selectively exchanging the chamfering cutter and the chamfering cutter provided in the head portion. Integrated sheet glass processing equipment. The method of claim 1, The glass block handler It includes a cover for preventing the scattering of debris generated during the glass block processing Integrated sheet glass processing equipment. The method of claim 2, The glass block handler It includes a work table for reciprocating along the upper surface of the body portion, The cover is rotatably connected to the work table Integrated sheet glass processing equipment. The method of claim 2, The cover is Only one side is open, The head portion correspondingly rotates to chamfer or chamfer the glass block through the open one side surface. Integrated sheet glass processing equipment. The method of claim 2, The glass block handler A support frame rotatably connected to an upper surface of the work table; It includes a pressure frame which is installed spaced apart from the support frame at a predetermined interval, The pressing frame is pressed in the supporting frame direction to fix the glass block located between the supporting frame and the pressing frame. Integrated sheet glass processing equipment. The method of claim 5, The pressing frame is Upper frame; A lower frame configured to be movable downward from the upper frame; and A pressurized cylinder provided between the upper frame and the lower frame and expanding or contracting by a fluid supplied from the outside; Integrated sheet glass processing equipment. The method of claim 1, The chamfer cutter Consisting of machining chamfer cutter or hole chamfer cutter Integrated sheet glass processing equipment. The method of claim 1, The changer is A support block provided on an upper surface of the body part; A rotating part rotatably provided on an upper surface of the support block; A turntable connected to the rotary part and to which the chamfering cutter and the chamfering cutter are fixed; Integrated sheet glass processing equipment. The method of claim 8, The turntable Formed of cross-shaped plates, Both sides are opened in the opposite direction to each other including a removable groove to which the chamfering cutter and the chamfering cutter can be fixed and a cutter support on which the chamfering cutter and the chamfering cutter is seated; Integrated sheet glass processing equipment. The method of claim 1, The changer is It is provided inside the head portion Integrated sheet glass processing equipment. A plurality of integrated thin glass processing apparatus according to any one of claims 1 to 10; An input / output table on which the glass block is seated; and It includes a transfer unit for transferring the glass block to the input and export surface plate or the integrated sheet glass processing apparatus  Machining assembly using integrated sheet glass processing equipment. The method of claim 11, The import / export table is The glass block includes a plurality of seating portion is seated Machining assembly using integrated sheet glass processing equipment. The method of claim 11, The transfer unit Configured to be movable along the connecting rail, Consists of a multi-joint robot having a hand grip portion for holding the glass block Machining assembly using integrated sheet glass processing equipment. The method of claim 11, The integrated sheet glass processing apparatus Equipped with six Machining assembly using integrated sheet glass processing equipment.

Images