TW201433532A - Transporting device - Google Patents

Abstract

The transporting device utilizing the gas to float the object to transport toward the first direction contains the upward-floating part, the transporting part and the suction part; the upward-floating part exerts positive pressure to the aforementioned object by means of spouting the aforementioned gas, so as to make the aforementioned object float; the transporting part comprises endless belt body extending towards the first direction and a plurality of bulges projecting from the aforementioned belt body to contact with the aforementioned object, which contacts with the aforementioned object to be driven towards the aforementioned first direction; the suction part is disposed to and in parallel extension with the aforementioned transporting part, or arranging on the same straight line as the aforementioned transporting part to exert negative pressure to the aforementioned object to make the aforementioned object in contact with the transporting part.

Description

Handling device

The present invention relates to a conveying device that transports a substrate such as thin glass and transports it.

In the manufacture of a flat panel display such as a liquid crystal display, in order to transport a substrate such as thin glass without damage, it is a transport device that transports the substrate by floating it. Such a conveying device usually includes a belt conveyor or a roller conveyor for discharging a compressed air floating device and having a driving force in contact with the floating substrate.

The surface of the dust and the adhesion of the dust on the glass substrate will have a significant impact on the quality of the display. One of the main causes of dust adhesion and surface scratches is that the glass substrate is in contact with a conveying device or the like. On the other hand, the glass substrate has flexibility because it has a thickness of, for example, 0.7 mm or less, and it is important to convey the substrate in a flat manner in order to prevent contact during transportation. In recent years, thinner glass has been demanded, and it has become increasingly difficult to carry it flat.

Patent Document 1 discloses a technique including a conveying device of a belt conveyor. According to this technique, the belt body is provided with protrusions arranged at equal intervals by making the protrusions It is conveyed by contact with the floating glass substrate.

Patent Document 2 discloses a technique including a conveying device of a roller conveyor. According to Patent Document 2, the technical problem recognized is that "the central portion of the passage of the glass substrate floats upward and hangs down to make the bending become remarkable." In order to solve this problem, the bending of the glass substrate is suppressed by adjusting the air supply amount of the air stage unit located at the center in the width direction.

[Patent Document 1] Japanese Patent Application No. 2008-066661

[Patent Document 2] Japanese Patent Application No. 2008-260591

The above technique maintains the glass substrate substantially flat. However, in the conveyance direction, there is still a technical problem with respect to local bending of the front end bending or the like. That is, when the glass substrate is moved from one roller to the next, or when moving from one carrier to the next, since the member supporting the front end is not provided, the front end is bent downward due to its own weight. . There is a problem that the front end easily collides with the roller or the conveying device.

The present invention has been developed in view of the above problems. In contrast to the above-mentioned technical knowledge, the inventors of the present invention completed the present invention by simply supporting both ends in the width direction of the glass substrate and slightly bending the central portion of the glass substrate to suppress the bending of the tip end.

According to an aspect of the invention, the gas is used to float the object to the first The transport device for transporting in one direction includes a floating portion, a transport portion, and a suction portion, and the floating portion applies a positive pressure to the object by ejecting the gas to float the object; and the transport portion includes the An endless belt extending in one direction, and a plurality of protrusions protruding from the belt body and contacting the object are configured to be in contact with the object and driven in the first direction; and the suction portion is disposed to be transported The portions are adjacent to each other and extend in parallel, or are arranged on the same straight line as the conveying portion, and apply a negative pressure to the object to bring the object into contact with the conveying portion.

The front end of the substrate can be prevented from being bent, and the substrate can be prevented from colliding with the conveying device or the like.

100‧‧‧Transportation device

112,312‧‧‧Transportation Department

112a, 322, 412a‧‧‧Attraction

114,314‧‧‧

116‧‧‧Upper

118‧‧‧Support table

120‧‧‧Decompression chamber

414‧‧‧ Roller

X‧‧‧Transportation direction

W‧‧‧Workpiece

G, G’‧‧‧ gas

Fig. 1 is a perspective view showing a part of a conveying device according to an embodiment of the present invention.

The second (a) to (c) drawings are three sides of the conveying device of the present embodiment.

Fig. 3 is a front cross-sectional view showing the floating portion of the present embodiment.

Fig. 4 is a front cross-sectional view showing the suction portion of the embodiment.

The fifth (a) and (b) drawings are front views of the suction portion and the conveying portion of the present embodiment.

Fig. 6(a)(b) is a front view showing a state in which the conveyance unit substrate is held flat.

Figure 7 is a side view showing how the substrate is bent near the center. Figure.

Fig. 8(a)(b) is a perspective view and a side view showing a part of the conveying device of another embodiment.

Fig. 9(a) and (b) are a perspective view and a plan view showing a part of the conveying device according to still another embodiment.

Fig. 10(a)(b) is a perspective view showing the substrate of the state in which the front end is bent by bending the vicinity of the center.

11(a) to (c) are explanatory diagrams for explaining the structure of the verification device.

Figure 12(a)(b) shows the verification results.

Several illustrative embodiments of the invention are described below with reference to the drawings.

The conveying device according to the embodiment of the present invention is suitable for conveying a thin object such as a glass substrate in, for example, a clean room. In the case of a glass substrate, it is not only about a thickness of about 0.7 mm, but also an extremely thin one having a thickness of about 0.1 to 0.3 mm.

Referring to Fig. 1 , a conveying device 100 according to an embodiment of the present invention includes a floating portion 116 for lifting a workpiece W (object), a conveying portion 112 for driving the workpiece W in a direction X (first direction), and The suction portion 112a that contacts the workpiece W with the conveying portion 112. The transport unit 112 includes a plurality of protrusions 114. The floating portion 116 is provided with an opening 116a for discharging a gas, and the discharged gas applies a positive pressure to the workpiece W to float the workpiece W. The suction portion 112a reversely applies a negative pressure to the workpiece W, and allows the workpiece W to be attracted. It is in contact with the front end of the protrusion 114. The conveyance unit 112 moves in the direction of the arrow X by means of a motor or the like, and the workpiece W is conveyed in the direction X. The workpiece W may be supported and transported only by the transport unit 112 without using the floating portion 116.

This will be explained in more detail with reference to Fig. 2. Both the transporting portion 112 and the floating portion 116 are supported by the support base 118, and the support base 118 is provided on the floor or grille of the clean room through the support leg 118a. The floating portion 116 is arranged on the support table 118, for example, a plurality of floating portions 116 are arranged in the direction X, and a plurality of floating portions 116 are also arranged in a direction (width direction) orthogonal to the direction X. The number of arrays can be freely selected, and thus the configuration of the device can be arbitrarily changed corresponding to the size of the object. The transport unit 112 is usually disposed at both ends in the width direction of the plurality of floating portions 116, but other arrangements are also possible.

Referring to Fig. 3, the floating portion 116 has a box shape as a whole, and its upper surface is substantially flat. A cavity 116b communicating with each other is provided inside the floating portion 116, and the cavity 116b communicates with the external gas supply device 122. The gas supply device 122 is a pump or a compressor that pressurizes the gas G such as air or nitrogen gas and supplies it to the floating portion 116.

A gas supply device 122 may be coupled to one of the upper floating portions 116, or a single gas supply device 122 may be coupled to the plurality of floating portions 116. In addition, the gas supply unit 122 can be in direct communication with the cavity 116b, and can also intervene between chambers that can store a certain amount of compressed gas.

The opening 116a that communicates with the cavity 116b is opened upward through the upper surface of the floating portion 116. The opening 116a is formed into a circular slit, for example, in FIGS. 1 and 2, and a rectangular shape, a plurality of slits, or a plurality of small holes, etc., may be used. Various shapes. Further, the opening 116a can penetrate vertically upward, and can also be inclined with respect to the upper surface. Alternatively, a part or the entire upper portion of the floating portion 116 may be a gas-permeable mesh body or a porous body.

The pressurized gas G supplied from the gas supply device 122 is ejected through the opening 116a through the cavity 116b. The gas G after the discharge generates a pressurizing space P between the workpiece W and the floating portion 116, thereby applying a positive pressure to the workpiece W and imparting a buoyancy force. At this time, in addition to the force generated by the ejected gas G colliding with the workpiece W, the static pressure generated during the process in which the collided gas G is dispersed toward the periphery also becomes a source of buoyancy. Therefore, a large buoyancy can be obtained with a slight pressing force, and the energy efficiency is excellent.

Referring again to Fig. 2, the transport unit 112 is provided with a belt conveyor having an endless belt, and the endless belt is wound between two or more runners 110. Each of the runners 110 is supported by a frame 102. As described above, the conveyance unit 112 is disposed at both ends in the width direction of the plurality of floating portions 116 so that the belt body extends in the direction X.

The main shaft 110a is coupled to the reel 110, and the main shaft 110a is pivotally supported by the support hole 102a of the frame 102, whereby the reel 110 can be rotated around it. The main shaft 110a is coupled to the gear 110b to be integrally rotatable. In the case of bonding, for example, a combination of a key and a key groove which are fitted to each other can be employed, and a structure in which the fitting is integrated instead of the fitting can be employed.

The conveying device 100 further has a driving device 110c such as an electric motor. The driving device 110c has a gear 110d that meshes with the gear 110b, and the steering wheel 110 is rotated by the driving of the driving device 110c, and the conveying portion 112 is rotated around the rotating wheel 110. Alternatively, the drive can also give the runner Direct drive, or further suitable gears, pinion gears.

The conveying portion 112 has a plurality of projections 114 that protrude from the belt body. A plurality of protrusions 114 are arranged along the direction X. The protrusions 114 may be formed integrally with the belt body or may be formed separately to be engaged with the belt body. The protrusions 114 are formed to be slightly higher than the floating height of the workpiece W as will be described later. The shape may be a cylinder, a rectangular parallelepiped, a cone or any other shape. Further, the front end thereof may be formed to be flat or formed in a spherical shape or a conical shape in order to reduce the contact area with the workpiece W. In addition, the front end can also have a lowered inclination toward the upper floating portion 116. This aspect will be explained later.

The suction portion 112a is arranged on the same straight line as the conveying portion 112. This line must be parallel to the direction X. More preferably, the attraction portion 112a and the projection 114 are located on the same straight line. The same line here means that the two do not have to be closely arranged on a single straight line, and may deviate from the straight line to a degree not exceeding a certain width. For example, when the belt width is 50 mm, about 20 mm from the center of the belt is an allowable width.

Referring to Fig. 4, the suction portion 112a is preferably formed integrally with the belt body and has a through hole communicating with the space under the belt body. The suction portion 112a sucks the gas G' directly under the workpiece W from the through hole, thereby causing the negative pressure NP to act on the workpiece W. The gas G' may be the same as the gas G described above, and other gases may be used.

Referring to Fig. 4 and Fig. 5, the suction portion 112a is formed to be slightly lower than the projections 114, thereby ensuring a suitable gap between the suction portion 112a and the workpiece W. The gas G' is attracted through the gap. Or it can be the same height. In this case, when the suction portion 112a attracts the gas G', the workpiece W and The suction portion 112a is in close contact.

The decompression chamber 120 is provided in close contact with the lower portion of the suction portion 112a. The decompression chamber 120 is connected to a gas G' suction means such as a pump or a compressor, and the internal space 120a is depressurized. The through hole 112b of the suction portion 112a communicates with the space 120a, thereby attracting the gas G'. The suction portion 112a and the space 120a may be always in communication, and may be configured to communicate only when the through hole 112b passes through a specific position.

The attraction portion 112a and the protrusion 114 are preferably alternately arranged. The attraction portion 112a and the protrusion 114 may be arranged at a ratio of 2:1 as shown in the drawing, and may be of any other ratio such as 1:1 or 1:2.

According to the present embodiment, as shown in Fig. 6(a), the suction portion 112a applies a negative pressure to the workpiece W, and the end portion of the workpiece W comes into contact with the projection 114. Since the projection 114 and the suction portion 112a are positioned on the same straight line, the end portion of the workpiece W can be attracted without being offset, and the flatness can be ensured. The end portion of the workpiece W is conveyed while traveling in contact with the projection 114.

The advantages of the present embodiment can be more clearly understood in comparison with the case of carrying by a roller as shown in Fig. 6(b). When the roller 10a is transported, the roller 10a does not travel together with the workpiece W, and as the tip end portion Wa of the workpiece W projects forward from the roller 10a, the tip end portion Wa is sagged by its own weight. As such, the front end portion Wa may hit the adjacent roller 10a. On the other hand, as can be understood from the sixth diagram (a), since the projection 114 and the workpiece W travel together, the projection 114 is not caught even if the front end of the conveyance direction is sagged. Further, the end of the workpiece W is a plurality of protrusions arranged in a row The 114 supports and moves with it, maintaining a flat shape like a ceiling supported by beams and columns.

Referring to Fig. 7, both ends in the width direction of the workpiece W are flatly supported to have a constant height, and on the other hand, the vicinity of the center of the workpiece W is slightly bent downward due to its own weight. That is, the workpiece W has a concave shape. Alternatively, a deformation means for bending the vicinity of the center of the workpiece W may be provided.

One of the deformation means is a gas supply device that produces a specific floating height H. The pressurized gas supplied from the gas supply means can be adjusted by the pressing force so that the floating height H on the floating portion 116 can be made lower than the height of the workpiece W on the projection 114. Alternatively, among the plurality of floating portions 116 arranged in the width direction, only the buoyancy above the center floating portion 116 may be reduced. Alternatively, an appropriate pressure drop means or flow rate adjusting means may be provided in the gas supply means or the floating portion 116 to reduce the buoyancy in the vicinity of the center. With this deformation means, the workpiece W can be made into a concave shape as shown in Fig. 7. Alternatively, the workpiece W may have a convex shape by enhancing the buoyancy generated by the floating portion 116.

Another example of the deformation means is that the projection 114 is configured to bend the workpiece W. The workpiece W has an inherent floating height H on the floating portion 116 depending on the weight of the workpiece W and the buoyancy force generated by the floating portion 116. When the projection 114 supports the workpiece W so as not to be bent at a height L2, the workpiece W can be formed into a concave shape as shown in Fig. 7 as long as the projection 114 is formed at a higher height L1.

Another example of the deformation means is that each front end of the protrusion 114 has an orientation The lowering of the transport portion 112. By tilting the projections 114, the vicinity of the center of the workpiece W can be caused to bend downward.

The above embodiment can have various modifications. Hereinafter, in particular, several embodiments of the deformation will be described with respect to the conveyance unit and the suction unit.

Fig. 8(a) shows one of the embodiments of the deformation in which the conveying portion 312 and the suction portion 322 are provided independently. The suction portion 322 extends adjacent to the transport portion 312 and extends in parallel, and the transport portion 312 may include a plurality of protrusions 314 as in the embodiment described above. The suction unit 322 includes a plurality of protrusions 322a arranged in parallel with the conveyance unit 312, and sucks the gas through the openings. It is preferable that the protrusion 314 is formed to be slightly higher than the protrusion 322a of the attraction portion 322. The suction portion 322 is directly connected to the gas G' suction means without passing through the decompression chamber.

Alternatively, other forms such as slits extending in parallel with the conveying portion 312 may be used instead of the projections 322a.

Alternatively, the suction portion may be provided with a cover outer cover, and the inside of the cover may be a negative pressure. This also belongs to the aspect in which the attraction portion is arranged on the same line as the transport portion. The entire conveyance unit is made to have a negative pressure, and the end portion of the workpiece W can be sucked without being offset, which is advantageous for ensuring flatness.

Further, as shown in FIG. 8(b), the flow path 330b that communicates with the suction portion 322 and the flow path 330a that communicates with the floating portion 116 are connected to each other, and the gas G may be circulated. These constitute a loop. In the case of a means 330 such as a pump or a compressor, it is advantageous to save energy based on the energy efficiency of the inflow and outflow balance. In this case, the single means 330 can serve as both a means for attracting the gas and a means for pressurizing the gas.

Alternatively, as shown in Fig. 9, the conveying portion may employ a roller conveyor. A plurality of rollers 414 are disposed along the direction X and rotatably supported by the frame 402. Preferably, a plurality of attracting portions 412a are alternately arranged on the same line as the plurality of rollers 414. Each of the main shafts of the roller 414 is coupled to the pulley 410b, and a driving device 410 such as an electric motor is also coupled to the pulley 410b. The pulleys 410b are coupled to each other by the belt 410e, and all the rollers 414 are rotated in synchronization. The main shaft 410c of the driving device 410 preferably extends to the opposite side end, and rotates the opposite side pulley 104b. Thereby, the rollers 414 at both ends are rotated in synchronization. Alternatively, the drive unit may be configured by a spindle and a gear mechanism without using a belt body. Similarly to the above-described embodiment, the suction portion 412a is connected to the suction means such as a pump or a compressor, and sucks the end of the workpiece W.

According to this aspect, both ends in the width direction of the workpiece W can be supported flat, and on the other hand, the vicinity of the center of the workpiece W can be slightly curved.

The effects that can be exhibited by the above embodiments will be described with reference to Fig. 10. Referring to Fig. 10(a), if the shape of the entire workpiece W is to be kept flat as in the prior art, when the front end of the workpiece W is not supported, the front end is bent downward as indicated by the arrow H due to its own weight. . This is the state, for example, when the workpiece W moves from one roller to the next, or from one carrier to the next. The workpiece W is easily bent against the roller or the conveying device because it is bent downward. On the other hand, according to the present embodiment, as shown in Fig. 10(b), both ends in the width direction of the workpiece W are flat along the conveyance direction X, but the vicinity of the center is slightly curved. So, the workpiece Since W is wavy in the width direction, the workpiece W cannot be freely deformed in the conveyance direction X, and the front end of the workpiece W is not bent downward even if it is not supported. Even when the workpiece W moves from one roller to the next, or when moving from one conveying device to the next, the front end of the workpiece W can be prevented from colliding with the roller or the conveying device.

Next, the effects that can be exhibited by the above embodiments are verified.

Fig. 11 is an explanatory view showing the configuration of the verification devices 500, 502. Figure 11(a) shows a plan view of the verification device 500, Figure 11(b) shows a side view of the arrow D of Figure 11(a), and Figure 11(c) shows the verification device 502 and the 11th (b) A side view of the position corresponding to the map. Here, the workpiece W is an aluminum plate of 1300 mm × 1000 mm × 0.3 mm.

As shown in the eleventh (a) and (b), the verification device 500 includes a floating portion 504 and a protruding portion 506. The floating portion 504 is the same as the floating portion 116, and is constituted by, for example, a discharge device that discharges compressed air, and a pressure lower than the pressure at which the workpiece W is horizontally generated is generated below the workpiece W. Therefore, the workpiece W is supported by the protrusion 506, and the central portion Wb is recessed vertically downward.

Further, as shown in FIG. 11(c), the verification device 502 includes a floating portion 504 and a protruding portion 508. The height of the protrusion 508 is lower than that of the protrusion 506, and the function of generating pressure of the floating portion 504 is stopped. Further, the workpiece W is supported in a flat state by the protruding portion 508 and the floating portion 504.

In the verification apparatuses 500 and 502, the workpiece W is held in the 11th (a) diagram, and the lower end portion Wa protrudes longer than the protrusions 506 and 508 by the length L2. The length L2 here is 200 mm.

Figure 12 shows the verification results. Fig. 12(a) shows a shape in which the arrow D in Fig. 11(a) shows the shape of the end portion Wa of the workpiece W, and Fig. 12(b) shows the attenuation characteristic of the workpiece W when the initial vibration is applied. In Fig. 12(a), the horizontal axis indicates the position at which the end portion Wa of the workpiece W protrudes from the projections 506 and 508, and the vertical axis indicates the height at the protruding position indicated by the horizontal axis of the end portion Wa. Further, in Fig. 12(b), the horizontal axis represents time (seconds), and the vertical axis represents the height of a certain measurement point of the end portion Wa.

Here, the solid line 510 indicates the measurement result when the verification device 500 is held such that the central portion Wb of the workpiece W is vertically recessed, and the broken line 512 indicates the measurement result when the workpiece W is flat by the verification device 502. .

As shown in Fig. 12(a), when the workpiece W is held in a flat state, the end portion Wa is drooped. On the other hand, in a state in which the central portion Wb of the workpiece W is recessed vertically downward, the sagging width of the end portion Wa is reduced to about 1/3 of that when the workpiece W is in a flat state.

Next, the time until the vibration is converged after the initial vibration is applied to the maximum amplitude is compared. As shown in Fig. 12(b), the time t2 in a state where the central portion Wb of the workpiece W is recessed vertically downward is shortened to half or less in comparison with the time t1 in a state where the workpiece W is kept flat.

As described above, in the verification device 502, the workpiece W comes into contact with the floating portion 504, and it is confirmed by another verification experiment that the contact between the workpiece W and the floating portion 504 does not affect the convergence of the vibration of the workpiece W.

It can be seen from the above that the conveying device according to any one of the embodiments of the present invention is only required to recess the central portion Wb of the workpiece W vertically downward. When the workpiece W is conveyed in the state, the sag of the end portion Wa of the workpiece W can be suppressed, and the vibration of the workpiece W can be reduced to achieve stable conveyance.

Although the invention has been described by way of preferred embodiments, the invention is not limited to the embodiments described above. In view of the above disclosure, those skilled in the art can change the embodiments and practice the invention.

[Industry Utilization]

A conveying device capable of preventing the front end of the substrate from being bent is provided.

100‧‧‧Transportation device

112‧‧‧Transportation Department

112a‧‧‧Attraction

114‧‧‧Protrusion

116‧‧‧Upper

116a‧‧‧ openings

X‧‧‧Transportation direction

W‧‧‧Workpiece

Claims (6)

A transport device that transports an object to the first direction by using a gas, and includes a floating portion, a transport portion, and a suction portion, and the floating portion applies a positive pressure to the object by ejecting the gas. The transporting portion includes an endless belt extending in the first direction, and a plurality of protrusions that protrude from the belt and are in contact with the object, and are configured to be in contact with the object. The suction portion is disposed adjacent to the transport portion and extends in parallel with the transport portion, and is provided on the same straight line as the transport portion, and applies a negative pressure to the object to bring the object into contact with the transport portion. . The conveying device according to claim 1, wherein the suction portion and the plurality of protrusions are alternately arranged along the first direction. The conveying device according to the first aspect of the invention, wherein the floating portion or the conveying portion includes a deforming means configured to bend the object in a center in a width direction thereof. The conveying device according to claim 3, wherein the deformation means is a gas supply device or the plurality of protrusions; and the gas supply device is configured to cause the floating portion to generate the object on the plurality of protrusions a height at which the height of the object is lower; and the plurality of protrusions are formed to be higher than a height of the object of the floating portion. The handling device of claim 1, wherein Further, the circulation unit is configured to circulate the gas sucked by the suction unit to the floating portion. The conveying device according to claim 1, wherein each of the plurality of projections has a front end that is inclined toward the floating portion.