KR20100136824A - Apparatus and method for applying a silicon damper onto a lcd frame by using cartesian robots - Google Patents

Abstract

PURPOSE: A device for attaching a silicon damper by using a robot and a method thereof, capable of the reduction of processing costs, is provided to reduce the material costs for a cushion by recycling silicon materials. CONSTITUTION: A device for attaching a silicon damper comprises a Y-axis movable unit(110), an X-axis movable unit(150), a Z-axis movable unit(170) and a pneumatic air supply unit(240). The Z-axis movable unit downward moves the long nozzle of a barrel using a Cartesian robot. The Y-axis and X-axis movable units transfer the long nozzles of barrel between the cutting holes at a fixed pattern.

Description

Apparatus and method for attaching a silicon damper using a robot {APPARATUS AND METHOD FOR APPLYING A SILICON DAMPER ONTO A LCD FRAME BY USING CARTESIAN ROBOTS}

The present invention relates to an apparatus and method for automatically attaching a cushion material for mounting a display window to a frame injection molding of an electronic device, and more particularly, in the process of using a silicon damper as a cushion material and mounting the same to a frame injection molding. By using Cartesian Robots and pneumatics, the silicone material is directly applied to the frame injection molding, dried, and integrally formed to reduce the processing cost and material cost according to the process automation and greatly improve the work productivity. The present invention relates to a silicon damper attachment device and method using a robot improved.

In general, various electronic devices including a mobile phone are provided with a display window such as an LCD for displaying information or inputting / outputting information.

Such an electronic device is provided with a frame injection molding 10, as shown in FIG. 1, wherein a cutting space 20 is formed in the center of the frame injection molding, and a cushion material 30 is attached to the edge thereof. A display window (not shown) is disposed on the cutting space 20, and a circumference thereof is supported by the cushion material 30 to protect the display window from an impact transmitted from the outside.

The conventional cushion material 30 mounted on the frame injection molding 10 of the electronic device is attached along the cutting space rim 20a of the frame injection molding 10 on which the display window is mounted. 30) uses a polyurethane foam (PO foam) called PORON (PORON).

The cushion material 30 of the polyurethane foam (PU foam) is a plate-like cushioning material, such a plate-like structure can not be attached directly along the cutting space rim 20a of the frame injection-molded product 10.

 Therefore, conventionally, the plate-like PORON raw material 32a and the double-sided tape 32b are laminated to secure an adhesive force, and then the PORON raw material 32a and the double-sided tape 32b are matched to various models of electronic devices. ) To cut and use.

Accordingly, the cushion material 30 cut to a certain size removes the medium from the back surface of the double-sided tape 32b, and is a PORON raw material 32a along the cutting space rim 20a of the frame injection molding 10 in the production line. And a double-sided tape 32b, and the display window is fixed on the cushion material 30 in a subsequent process.

Therefore, the conventional work process as described above has a problem in that the work productivity is low because the process of cutting the cushion material 30 and attaching it to each frame injection molding 10 is performed by hand.

In addition, the conventional cushioning material 30 should be cut in accordance with the cutting space rim 20a of the frame injection molding 10. When the cushioning material 30 is cut in this way, the cutting space of the frame injection molding 10 ( 20) since the raw material has to be cut, there is a problem that the material cost loss of the cushion material 30 becomes large.

In addition, in the conventional cushion material 30, since the PORON raw material 32a is attached to the frame injection molded product 10 through the double-sided tape 32b, when the plastic injection molded product is disposed of by disposing of the electronic device, The double-sided tape 32b acts as an impurity, which is undesirable in terms of recycling waste.

The present invention is to solve the conventional problems as described above, the object is to improve the work productivity according to the process automation in the process of mounting the cushion material to the frame injection molding to greatly reduce the processing cost, the cushion as much as the cutting space of the frame injection The present invention provides an apparatus and method for attaching a silicon damper using a robot that is improved to significantly reduce the cost of cushioning materials without having to discard materials.

Another object of the present invention is to use a silicon material as a cushion material, and by using a separate double-sided tape to minimize the inclusion of impurities in the recycling of plastic waste by using a silicon improved robot to facilitate waste recycling A damper attachment device and method are provided.

In order to achieve the above object, the device for attaching a silicon damper using the robot of the present invention is a device for automatically attaching cushion material to a frame injection product of an electronic device, the Y-axis extending between front and rear edges of a predetermined size. And a Y-axis slider which moves in the Y-axis direction by the operation of a built-in driving motor on the upper part of the Y-axis, and a jig in which a plurality of frame injection-molded parts are fixed to the upper surface is provided. A Y-axis moving unit to move the frame injection-molders along the Y-axis EMS guide; An X-axis slider having an X-axis guide to extend the upper end of the plurality of supports extending from both sides of the base to the upper side, the X-axis slider to move in the X-axis direction by the operation of the built-in drive motor at the top of the X-axis guide X-axis moving unit provided; A Z-axis moving part having an upper end connected to the X-axis slider and having a Z-axis cylinder body extending in a vertical direction, and a lower end of the cylinder body having a lift table moving in the vertical Z-axis direction by pneumatic operation; A plurality of barrels mounted side by side through a barrel holder on the platform of the Z-axis mobile unit, and the inside of the barrel contains a silicon material, the upper end of the barrel is connected to each pneumatic tube, the lower end of each barrel A material supply part in which the nozzle protrudes downward; And a pneumatic supply unit connected to each of the barrels of the material supply unit through a pneumatic tube, providing a pneumatic pressure of the predetermined pressure to the pneumatic tube to increase the internal pressure of the barrel, and discharging the silicon material from the barrel through the long nozzle. And the Z-axis moving unit lowers the long nozzles of the barrel to the cutting space rim of each of the frame injection moldings mounted on the jig, and the Y-axis moving unit and the X-axis moving unit cuts the long nozzles of the barrel to the cutting of the frame injection moldings. The pneumatic supply unit provides pneumatic pressure to each barrel through the pneumatic tube to discharge the silicon material from the long nozzle along the cutting space edge of the frame injections, after the application of the silicon material is completed. The Z-axis moving unit raises the long nozzles of the barrel, and the jig To separate the frame injection moldings. Therefore, the present invention uses a rectangular coordinate robot consisting of the Y-axis moving unit, the X-axis moving unit and the Z-axis moving unit to apply the silicon material through the long nozzle while the barrels containing the silicon material move along the cutting space edge of the frame injection. And unattended automation of the process is implemented.

In order to achieve the above object, the method of attaching a silicon damper using the robot of the present invention is a method for automatically attaching a cushion material to a frame injection product of an electronic device, the Y axis extending between the base front and rear edges of a predetermined size. An upper surface of the plurality of frame injection-molded parts through the jig on the slider of the Y-axis moving unit having an LM guide and having a Y-axis slider moving in the Y-axis direction by the operation of a built-in drive motor at the top of the Y-axis LM guide. Fixing to; An X-axis slider having an X-axis guide to extend the upper end of the plurality of supports extending from both sides of the base to the upper side, the X-axis slider to move in the X-axis direction by the operation of the built-in drive motor at the top of the X-axis guide The X-axis moving unit provided with, and the upper end is connected to the X-axis slider, and has a Z-axis cylinder body extending in the vertical direction, the lower end of the cylinder body is provided with a lifting table for moving in the vertical Z-axis direction by pneumatic operation A plurality of barrels are placed on the platform so as to be movable in the X-axis and Z-axis directions through the moved Z-axis moving part, and a silicon material is filled therein so that the silicon material is operated by the X-axis moving part and the Z-axis moving part. Arranging to be movable in the axial and Z-axis directions; The barrel is connected to each barrel through a pneumatic tube of the pneumatic supply unit, and if the pneumatic tube is provided with a predetermined pressure, the internal pressure of the barrel is increased to prepare the silicon material to be discharged through the long nozzles formed at the bottom of each barrel. step; The Z-axis moving unit lowers the long nozzles of the barrel to the cutting space edge of each of the frame injection moldings mounted on the jig, the Y-axis moving unit moves the jig on which the frame injection moldings are mounted, and the X-axis moving unit moves the barrels. Silicone material along the cutting space rim of the frame injections from the long nozzle by providing pneumatics to each barrel through the pneumatic tube, while simultaneously allowing the long nozzles of the barrel to move in a predetermined pattern along the cutting space rim of the frame injection moldings. Applying a; And after the application of the silicon material is completed, the Z-axis moving unit raises the barrel's long nozzles and separates the frame injection moldings from the jig. As described above, the present invention can achieve unmanned process automation by using an orthogonal coordinate robot composed of a Y-axis moving unit, an X-axis moving unit, and a Z-axis moving unit, and can greatly reduce the processing cost by improving the work productivity, and the silicon in the frame injection molding. Since the coating operation is performed along the cutting space edge of the frame injection molding in the process of applying the material, it is possible to significantly reduce the cost of the cushioning material without having to discard the cushioning material without uselessly.

According to the apparatus and method for attaching a silicon damper using a robot according to the present invention, in the process of mounting the cushion material to the frame injection molding, the barrel containing silicon material is moved along the cutting space edge of the frame injection molding using a rectangular coordinate robot. Process automation of applying the silicon material is realized through.

Therefore, unmanned process automation can improve work productivity and greatly reduce the processing cost. In the process of applying the silicon material to the frame injection molding, the coating work is performed along the cutting space edge of the frame injection molding. There is no need to dispose, which can greatly reduce the cost of the cushion material.

In addition, according to the present invention, since a silicone material may be used as a cushion material and cured so as to be utilized as a silicon damper, it is not necessary to use a separate double-sided tape. A useful effect of smooth recycling is obtained.

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

The silicon damper attachment device 100 using the robot according to the present invention includes a Y-axis moving part 110 for moving the frame injection product 10 in the Y-axis direction as shown in FIG. 2. Such a Y-axis moving unit 110 is formed on the base 112 of a predetermined size.

Such a Y-axis moving unit 110 includes a Y-axis L-m guide 120 extending in the front-rear corner direction near the center of the base 112. The Y-axis LM guide 120 has a plurality of Y-axis sliders 122 mounted thereon, such a Y-axis slider 122 is a Y-axis LM guide 120 by the operation of a built-in drive motor (not shown). Each moves linearly along

Such a structure in which the Y-axis slider 122 moves along the Y-axis guide 120 in the Y-axis moving unit 110 to the operation of the driving motor is a linear moving device used in conventional Cartesian Robots. You can use (Linear Moving Device). For example, such a rectangular coordinate robot may have the same structure as a rectangular coordinate robot XM 3000 series manufactured by Epson Co., Ltd., which is manufactured and sold in the art, and is a linear driving device provided in such a rectangular coordinate robot. Implementable

Alternatively, it may be made of a structure for linearly moving the mechanical parts mounted on the slider through the drive motor, such as "workpiece linear transfer device" of Patent No. 0327540.

The Y-axis moving unit 110 includes a drive motor (not shown) inside the base 112, and the Y-axis slider 122 is disposed on a screw shaft (not shown) rotated by the drive motor. Screwed and moved along the Y-axis guide 120, or the Y-axis slider 122 is moved back and forth linearly on the Y-axis guide 120 through a belt (not shown) rotated by a drive motor. The present invention is applicable to all of these structures.

In addition, the Y-axis moving unit 110 has a jig 130 having a plurality of frame injection-molded products 10 fixed to the upper surface on the Y-axis slider 122, and through the movement of the Y-axis slider 122 The frame injection moldings 10 are linearly moved along the Y-axis EMS guide 120.

As described above, the jig 130 for fixing the frame injection moldings 10 forms a concave groove 132 corresponding to the shape of the frame injection molding 10 on the upper surface thereof, thereby forming the frame injection moldings 10 in the recess groove 132. Insert and fix. In addition, the jig 130 forms a plurality of concave grooves 132 on the upper surface thereof. For example, as shown in FIG. 3, five frames are formed by forming one row of five concave grooves 132 side by side. The injection molding 10 may be mounted, or alternatively, the two frame five recesses 132 may be formed side by side to simultaneously mount 10 frame injection moldings 10.

In addition, according to the number of the frame injection moldings 10 mounted on the jig 130 as described above, the barrels 210 of the material supply unit 200 to be described later are respectively one row 5 according to the number of the frame injection moldings 10, Or two rows of five.

In addition, the silicon damper attachment apparatus 100 using the robot according to the present invention is provided with an X-axis moving part 150 through the upper end of the plurality of supports (140a, 140b) extending from the upper side from both corners of the base (112). do. The X-axis moving unit 150 has an X-axis LM guide 152 extending between the plurality of supports (140a, 140b), the drive motor built in the upper portion of the X-axis LM guide 152 It is a structure provided with the X-axis slider 154 which moves to an X-axis direction by operation of (not shown).

Similar to the structure of the Y-axis moving unit 110, the structure of the X-axis moving unit 150, the linear drive device utilized in the Cartesian coordinate robot, or the "workpiece linear transfer device" proposed in Patent Registration No. 0327540 Is made of the same structure.

Therefore, the X-axis slider 154 of the X-axis moving unit 150 moves in a direction orthogonal to the Y-axis slider 122 of the Y-axis moving unit 110.

In addition, the silicon damper attachment device 100 using the robot according to the present invention is connected to the upper end of the X-axis slider 154 Z axis moving unit 170 for moving up and down the barrel 210 containing the silicon material (S) It is provided.

The Z-axis moving unit 170 is fixed to the X-axis slider 154, the upper end is integrally provided with a Z-axis cylinder body 172 extending in the vertical direction, the lower end of the cylinder body 172 is pneumatic It is a structure arranged so that the lifting platform 180 moving in the vertical Z-axis direction by the operation.

Such a Z-axis moving unit 170 has a structure of a pneumatic cylinder, a piston (not shown) is mounted inside the cylinder body 172 to move up and down, the lower rod of the piston is the cylinder body Exposed to the lower end of 172, the platform 180 is integrally fixed.

Therefore, such a Z-axis moving unit 170 is a pneumatic operation when the piston moves up and down in the interior of the cylinder body 172, the platform 180 is moved up and down in conjunction with it.

Such a Z-axis moving unit 170, for example, such as the "linear drive device" of Patent Publication No. 195-0003066 may be adopted a structure that allows the piston to move up and down inside the cylinder body by pneumatic operation.

In addition, the platform 180 of the Z-axis moving unit 170 is orthogonal to the X-axis slider 154 of the X-axis moving unit 150 and the Y-axis slider 122 of the Y-axis moving unit 110. Go to.

In addition, the silicon damper attachment apparatus 100 using the robot according to the present invention has a material supply unit 200 mounted on a lift table 180 of the Z-axis moving unit 170 to move up and down, the material supply unit 200. The barrel holder 202 is horizontally mounted in parallel to the platform 180, and a plurality of barrels 210 are mounted side by side on the barrel holder 202.

The barrel 210 structure of the material supply unit 200 is illustrated in FIGS. 3 and 5. The inside of the barrel 210 is filled with a silicon material (S), the top of the barrel 210 is covered with a cap 214, the cap 214 is connected to the pneumatic tube 242, respectively, Long nozzles 220 are formed at the bottom of the barrel 210 to protrude downward.

In addition, the barrels 210 of the material supply unit 200 are connected to each of the pneumatic supply unit 240 through a pneumatic tube 242, such a pneumatic supply unit 240 is X of the X-axis moving unit 150 A pneumatic tank 264 and a pneumatic pump 266 are built into the casing 262 arranged at a predetermined height parallel to the shaft slider 154, and an air pressure regulator 268 is provided from the pneumatic tank 264. And a constant pressure of the pneumatic tube 242 through the on-off valve 270.

In the pneumatic supply unit 240, the pneumatic tank 264 is maintained at a constant pressure by the pump 266, and when the on / off valve 270 is opened, high pressure air is supplied to the pneumatic tube 242 through the pneumatic regulator 268. to provide.

Therefore, the internal pressure of the barrel 210 connected to the pneumatic tube 242 is increased, and the silicon material S is discharged from the barrel 210 through the long nozzle 220. In addition, when the closing valve 270 is closed, the internal pressure of the barrel 210 does not increase, so that the discharge of the silicon material S from the long nozzle 220 is stopped. In this manner, the silicon material S is discharged quantitatively from the long nozzle 220 in the process of opening and closing the on / off valve 270.

In the silicon damper attachment device 100 using the robot according to the present invention having the structure as described above, the jig 130 fixed on the Y-axis slider 122 is disposed on the lower side of the Z-axis moving part 170. When lowering the platform 180 through the Z-axis moving unit 170, a plurality of barrels 210 are each of the long nozzles 220 are mounted on the jig 130, as shown in FIG. Is lowered to the cutting space rim 20a of the frame injection moldings 10.

In this state, the Y-axis moving unit 110 and the X-axis moving unit 150 move the long nozzles 220 of the barrel 210 along the cutting space edge 20a of the frame injection moldings 10. At the same time, the pneumatic supply 240 provides pneumatic pressure to each barrel 210 through the pneumatic tube 242 to remove the cutting space rim 20a of the frame injection moldings 10 from the long nozzle 220. Therefore, the silicon material S is discharged.

In this case, the Y-axis moving unit 110 moves the frame injection product 10 to the Y-axis through the Y-axis slider 122 and barrels the X-axis moving unit 150 through the X-axis slider 154. Move 210 in the X-axis direction. By combining the Y-axis moving unit 110 and the X-axis moving unit 150 as described above, the long nozzles 220 of the barrel 210 have a predetermined pattern along the cutting space rim 20a of the respective frame injection moldings 10. 6, the silicon material S is applied.

In this case, the barrel 210 is coated with a single line of silicon material S along the cutting space rim 20a of the frame injection-molded product 10, as shown in FIG. 7A through the long nozzle 220, Two rows of silicone material S are applied side by side, or the silicone material S is applied in the form of a plurality of corrugated patterns. As such, the height h of the silicon material S applied along the cutting space edge 20a on the frame injection molding 10 may be formed by the long nozzle 220 at least 0.3 mm.

After the application of the silicon material S is completed by the operation, the Z-axis moving unit 170 raises the long nozzles 220 of the barrel 210, and the frame injection molded product 10 from the jig 130. ) To separate the silicone material (S) of the frame injection molding (10) in a separate place, and to harden to form a silicon damper on the cutting space rim 20a of the frame injection molding (10).

Hereinafter, the silicon damper attaching method using the silicon damper attaching device 100 using the robot according to the present invention will be described in more detail.

The method for attaching a silicon damper using a robot according to the present invention includes a Y-axis L guide 120 extending between front and rear edges of a base 112 of a predetermined size, and built in an upper portion of the Y-axis guide L 120. In order to move the plurality of frame injection products 10 in the Y-axis direction by using the Y-axis moving unit 110 having the Y-axis slider 122 moving in the Y-axis direction by the operation of the driven motor (not shown). The mounting step takes place.

That is, when the jig 130 is fixed to the upper portion of the Y-axis slider 122 and the plurality of frame injection moldings 10 are fixed to the concave grooves 132 provided in the jig 130, the Y-axis moving part 110 is fixed. A plurality of frame injection moldings 10 can be mounted to be movable in the Y axis direction.

In addition, the X-axis moving unit 150 and the Z-axis moving unit 170 are arranged to move the plurality of barrels 210 in the X-axis and Z-axis directions. Is provided with an X-axis LM guide 152 extending from the upper side to the upper side from both edges of the base 112, the X-axis LM guide 152, and built in the upper portion of the X-axis LM guide 152 Z-axis cylinder body 172 of the Z-axis moving unit 170 to the X-axis slider 154 has a structure having an X-axis slider 154 to move in the X-axis direction by the operation of a drive motor (not shown). Is a structure that is connected.

In addition, the Z-axis moving unit 170 is provided at the lower end of the cylinder body 172, the lifting table 180 to move in the vertical Z-axis direction by pneumatic operation, the lifting table 180 through the barrel holder 202 As the barrels 210 are fixed, the barrels 210 are arranged to be movable along the X-axis and Z-axis directions by the operation of the X-axis moving unit 150 and the Z-axis moving unit 170. The silicon material S is filled in the barrel 210.

Then, the step of preparing the silicon material (S) is discharged through the long nozzle 220 of the barrel 210, the barrel 210 is the pneumatic pressure of the pneumatic supply unit 240 on each upper end thereof. When the tube 242 is connected and the pneumatic tube 242 is provided with a predetermined pressure to increase the internal pressure of the barrel 210, the silicon material S is discharged from the long nozzle 220 of the barrel 210. Be prepared.

In addition, applying pressure to each barrel 210 is applied to the silicone material S from the long nozzle 220 along the cutting space rim 20a of the frame injection moldings 10.

In this step, the Z-axis moving unit 170 lowers the long nozzles 220 of the barrel 210 to the cutting space rim 20a of each of the frame injection moldings 10 mounted on the jig 130. The Y-axis moving unit 110 moves the jig 130 on which the frame injection products 10 are mounted in the Y-axis direction, and the X-axis moving unit 150 moves the barrels 210 in the X-axis direction. The long nozzles 220 of the barrel 210 are respectively moved in a predetermined pattern along the cutting space rim 20a of the frame injection moldings 10, while simultaneously supplying air pressure to the barrel 210 through the pneumatic tube 242. Then, the silicone material S is applied from the long nozzle 220 along the cutting space rim 20a of the frame injection moldings 10.

In this case, the step of applying the silicon material (S) is to apply a line of silicon material (S) along the cutting space rim 20a of the frame injection molding 10 through the long nozzle 220 of the barrel 210. Alternatively, two rows of silicone material S are applied side by side, or the silicone material S is applied in the form of a plurality of corrugated patterns. In addition, in this process, the silicon material (S) is applied so that its height is made at least 0.3mm along the cutting space edge (20a) of the frame injection molding (10).

After the application of the silicon material S is completed as described above, the Z-axis moving unit 170 raises the long nozzles 220 of the barrel 210 and removes the frame injection moldings 10 from the jig 130. Separation step is made to complete the application of the silicon material (S).

In addition, the present invention is to separate the frame injection moldings 10 from the jig 130 after the application of the silicon material (S) is completed as described above, this step vacuums the frame injection moldings 10 from the jig 130 It is separated by adsorption. In this case, the present invention is provided with a separate vacuum suction device (not shown) to vacuum the frame injection-molded product 10 from the jig 130, separated from the concave groove 132 of the jig 130 in a separate place Can be moved to

In the method of attaching a silicon damper using a robot according to the present invention, the frame injection moldings 10 are separated from the jig 130 by a vacuum suction method, and then the frame injection moldings 10 are dried. In this case, the frame injection moldings 10 are left to dry at room temperature or dried at least 15 to 30 minutes in a state of 70% humidity to be cured with a silicon damper.

As described above, according to the apparatus and method for attaching the silicon damper using the robot of the present invention, the Y-axis moving part 110, the X-axis moving part 150, and the Z-axis moving part ( The silicon material S is moved through the long nozzle 220 while the barrels 210 containing the silicon material S are moved along the cutting space rim 20a of the frame injection molding 10 using the rectangular coordinate robot 170. Process automation for applying the coating is implemented. Therefore, it is possible to greatly reduce the processing cost by improving the work productivity through the unmanned process automation, and apply along the cutting space rim 20a of the frame injection molding 10 in the process of applying the silicon material (S) to the frame injection molding 10 Since the operation is performed unattended automatically, the cushion material cost can be greatly reduced compared to the conventional method without unnecessary disposal of the cushion material.

In addition, according to the present invention, since the silicon material (S) as a cushion material can be utilized, and it can be cured and used as a silicon damper, it is not necessary to use a separate double-sided tape. Waste recycling can be carried out smoothly.

Although the present invention has been described in detail with reference to the accompanying drawings, the present invention is not limited to such a specific structure. Those skilled in the art will be able to variously modify or change the embodiments of the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Nevertheless, it will be apparent that all such modifications or design modifications to such simple embodiments will clearly fall within the scope of the present invention.

1 is an external perspective view showing a state in which a cushion member is mounted on a frame injection molded product of an electronic apparatus according to the related art.

Figure 2 is an external perspective view showing the silicon damper attachment device using a robot according to the invention as a whole.

3 is a perspective view illustrating a jig and a material supply unit in a silicon damper attachment apparatus using a robot according to the present invention.

Figure 4 is an external perspective view showing a state in which the silicon material is applied to the frame injection molding in the silicon damper attachment device using a robot according to the present invention.

5 is a cross-sectional view showing a barrel provided in the silicon damper attachment device using a robot according to the present invention.

Figure 6 is a perspective view of a silicon material is applied on the frame injection molding by the silicon damper attachment device using a robot according to the present invention.

FIG. 7A is an explanatory view showing a state in which a silicon material is coated on a frame injection molded product in a predetermined pattern by a silicon damper attachment apparatus using a robot according to the present invention. FIG.

7B is an explanatory view showing the thickness of the silicon damper formed on the frame injection molded by the silicon damper attachment device using a robot according to the present invention.

Description of the Related Art

10 ..... Frame Injection 20 ..... Cutting Space

20a .... cutting space border 30 ..... cushion material

32a .... PORON Raw Material 32b .... Double Sided Tape

100 .... Silicon damper attachment device using a robot according to the present invention

110 .... Y-axis moving part 112 ..... Base

120 .... Y-axis LM guide 122 ..... Y-axis slider

130 .... Jig 132 .....

140a, 140b .... Support 150 ..... X-axis moving part

152 .... X-axis LM Guide 154 ..... X-axis Slider

170 .... Z axis moving part 172 ..... Z axis cylinder body

180 .... Platform 200 ..... Material Supply

202 ... barrel holder 210 ... barrel

214 .... Cap 220 ..... Long nozzle

240 .... pneumatic supply 262 ..... casing

264 .. Pneumatic tanks 266 ..... Pneumatic pumps

268 .... Air Pressure Regulator

270 .... Valves h ..... Height of silicone material

S ..... silicone material

Claims (10)

An apparatus for automatically attaching cushion material to a frame injection product of an electronic device, Y-axis having a Y-axis guide 120 extending between the front and rear corners of a predetermined size 112, the Y-axis moving in the Y-axis direction by the operation of the built-in drive motor from the top of the Y-axis guide (120) Y-axis having a slider 122 and a jig 130 having a plurality of frame injection moldings 10 fixed to an upper surface thereof is disposed on the slider to move the frame injection moldings 10 along the Y-axis LM guide 120. Moving unit 110; It is provided with an X-axis LM guide 152 extending from the upper side of the base 112, the upper side of the plurality of support (140a, 140b), the upper portion of the X-axis LM guide 152 An X-axis moving part 150 having an X-axis slider 154 moving in the X-axis direction by the operation of the drive motor; An upper end is connected to the X-axis slider 154, and has a Z-axis cylinder body 172 extending in the vertical direction, and a lower end of the cylinder body 172 moves in the vertical Z-axis direction by pneumatic operation ( 180 is provided with a Z-axis moving unit 170; The barrel 180 of the Z-axis moving unit 170 is provided with a plurality of barrels 210 mounted side by side through the barrel holder 202, the silicon material (S) is contained in the barrel (210) A pneumatic tube 242 is connected to an upper end of the barrel 210, and a long nozzle 220 protrudes downward from a lower end of the barrel 210; And Is connected to each of the barrel 210 of the material supply unit 200 through a pneumatic tube 242, to increase the internal pressure of the barrel 210 by providing a pneumatic pressure of a predetermined pressure to the pneumatic tube 242, the long nozzle Pneumatic supply unit 240 for discharging the silicon material (S) from the barrel 210 through the 220, wherein the Z-axis moving unit 170 jig the long nozzles 220 of the barrel 210 Lower the cutting space rim 20a of each of the frame injection moldings 10 mounted on the 130, and the Y-axis moving unit 110 and the X-axis moving unit 150 are long nozzles of the barrel 210 ( 220 are moved in a predetermined pattern along the cutting space rim 20a of the frame injection moldings 10, and the pneumatic supply unit 240 supplies pneumatic pressure to each barrel 210 through the pneumatic tube 242. The silicon material S is discharged from the nozzle 220 along the cutting space rim 20a of the frame injection moldings 10, and the silicon After the application of the material S is completed, the Z-axis moving unit 170 is configured to raise the long nozzles 220 of the barrel 210 and separate the frame injection-molded products 10 from the jig 130. Silicon damper attachment device 100 using a robot, characterized in that. According to claim 1, wherein the jig 130 is to form a concave groove 132 corresponding to the shape of the frame injection molded product 10 on the upper surface to fix the frame injection molded product 10 into the concave groove 132 to fix. Silicon damper attachment device 100 using a robot characterized in that. According to claim 2, The jig 130 is formed in one row of five concave grooves 132 side by side to mount five frame injection moldings 10, or two rows of five concave grooves 132 Forming side by side to mount the ten frame injection molding (10), the silicon damper attachment device using a robot, characterized in that the barrel 210 of the material supply unit 200 is provided in accordance with the number of the frame injection molding (10) 100. According to claim 1, wherein the barrel 210 is applied through a long nozzle 220, one line of silicone material (S) along the cutting space rim 20a of the frame injection molding 10, or two lines of silicone Silicon damper attachment device 100 using a robot, characterized in that to apply the material (S) side by side, or to apply the silicon material (S) in the form of a plurality of corrugated patterns. The method according to claim 4, wherein the frame injection molding (10) is attached to the silicon damper using a robot, characterized in that the height (h) of the silicon material (S) applied along the cutting space edge (20a) is at least 0.3mm or more. Device 100. In the method for automatically attaching the cushion material to the frame injection molding of the electronic device, Y-axis having an Y-axis guide 120 extending between the front and rear corners of the base 112 of a predetermined size, the Y-axis moving in the Y-axis direction by the operation of the built-in drive motor from the top of the Y-axis guide (120) Fixing a plurality of frame injection-molded products (10) to an upper surface through a jig (130) on a slider of a Y-axis moving part (110) having a slider (122); It is provided with an X-axis LM guide 152 extending from the upper side of the base 112, the upper side of the plurality of support (140a, 140b), the upper portion of the X-axis LM guide 152 An X-axis moving part 150 having an X-axis slider 154 moving in the X-axis direction by the operation of the drive motor, and a Z-axis cylinder connected to an upper end of the X-axis slider 154 and extending in the vertical direction. The body 172, the lower end of the cylinder body 172 in the X-axis and Z-axis direction through the Z-axis moving unit 170 is provided with a lifting platform 180 to move in the vertical Z-axis direction by pneumatic operation A plurality of barrels 210 are disposed on the platform 180 so as to be movable, and the silicon material S is filled in the silicon material S, respectively, so that the silicon material S is moved between the X-axis moving part 150 and the Z-axis moving part ( Arranging to be movable in the X-axis and Z-axis directions by the operation of 170); The barrels 210 are connected to each of the barrels 210 through a pneumatic tube 242 of the pneumatic supply unit 240, and when the pneumatic tube 242 is provided with a predetermined pressure, the internal pressure of the barrel 210 is raised to raise the barrel 210. Preparing to discharge the silicon material (S) through the long nozzle 220 formed in each lower portion; The Z-axis moving unit 170 lowers the long nozzles 220 of the barrel 210 to the cutting space edge 20a of each of the frame injection moldings 10 mounted on the jig 130, and the Y-axis moving unit 110 moves the jig 130 in which the frame injection moldings 10 are mounted, and the X-axis moving unit 150 moves the barrels 210 so that the long nozzles 220 of the barrels 210 are respectively. While being moved in a predetermined pattern along the cutting space rim 20a of the frame injection moldings 10, the pneumatic tube 242 provides pneumatic pressure to each barrel 210 through the frame injection molding from the long nozzle 220. Applying the silicon material S along the cutting space rim 20a of (10); And, After the application of the silicon material S is completed, the Z-axis moving unit 170 raises the long nozzles 220 of the barrel 210 and separates the frame injection moldings 10 from the jig 130. Step; attaching the silicon damper using a robot, characterized in that it comprises a. The method of claim 6, wherein the applying of the silicon material (S) is performed through the long nozzle 220 of the barrel 210 along the cutting space rim 20a of the frame injection molding 10. ), Or apply two rows of silicon material (S) side by side, or apply a silicon material (S) in the form of a plurality of corrugated patterns. 8. The method of claim 7, wherein the step of applying the silicon material (S) is such that the height (h) of the silicon material (S) is at least 0.3mm along the cutting space edge (20a) of the frame injection molding (10). Silicon damper attachment method using a robot, characterized in that to apply. The method of attaching a silicon damper using a robot according to claim 6, wherein the separating the frame injection moldings 10 from the jig 130 is to separate the frame injection moldings 10 from the jig 130 by vacuum suction method. . The method of claim 9, after the step of separating the frame injection moldings 10 from the jig 130, the frame injection moldings 10 to dry at room temperature, or at least 15 to 30 minutes drying in a state of 70% humidity Silicon damper attachment method using a robot, characterized in that to make.

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