JP2014037042A - Frame transport device and frame transport method using the same - Google Patents

Abstract

The present invention provides a frame holding device for a substrate holding frame for preventing a substrate damage accident, preventing a shift when stacking the substrate holding frames, and taking out the stacked substrate holding frames. To provide.
Stable transport is possible by having a correction function for correcting the position and tilt of the robot hand based on the position information of the frame detected by the position sensor provided in the robot hand of the frame transport device. And
[Selection] Figure 1

Description

According to the present invention, a rigid (flexible) rectangular substrate is placed one by one on a substrate support plate provided on the inner periphery of a rectangular substrate holding frame, and the substrates are The present invention relates to a frame transport apparatus for stacking a substrate holding frame or a substrate holding frame itself in a multi-stage and a frame transport method using the frame transport apparatus.
An example of the substrate is a thin glass substrate, and in particular, a plasma display, an organic EL display, a color filter substrate for a liquid crystal display device, an intermediate product thereof, and other various substrates can be exemplified.

The present invention prevents misalignment when stacking substrate holding frames in order to prevent substrate damage, and also provides a substrate holding frame that is shifted and stacked due to an impact when loaded or transported. The present invention relates to a frame carrying device for a substrate holding frame for taking out and a frame carrying method using the frame carrying device.

It is important that a substrate used for a color filter for a liquid crystal display, a plasma display, an organic EL display, etc. be transported and stored without being damaged or soiled. When transporting such a plate-like object, it is necessary to store in parallel at a predetermined interval so that the substrates do not contact each other.
However, flat panel display products represented by these liquid crystal display, plasma display, and organic EL display are manufactured in a multi-faceted state, even if the display device itself is upsized, even if it is a small size product. For this reason, the substrate used and its intermediate products have been increased in size, and when the size is about 1 meter square, even if a 0.7 mm thick glass substrate supports two or four sides facing each other, It is inevitable that the intermediate portion is bent downward (gravity direction) by 100 mm or more. Substrates are required to have a size of 2 square meters or more, and it is necessary to store and handle such substrates with high density and safety due to problems of storage space and handling equipment.

Patent Document 1 relates to a tray stacking / transferring apparatus that stacks, transfers, and places trays for transporting glass substrates and the like. There is a large difference in the overall weight when the number of trays is increased and the tray is empty and when a substrate is stored, and the tray position may be shifted due to accumulation due to a dimensional error of the tray. Each side edge of the stacking tray is brought into contact with and pressed by an elastic pressing body to adjust the position.
This is a method in which the transport device presses the side surface of the frame to correct the position, and a method for detecting the position of the frame by the transport device and gripping the frame based on the corrected position is not described.

JP 2007-261738 A

Substrate storage devices and transport devices that store and transport glass substrates in large quantities are required to save space in order to increase production efficiency and transport efficiency. On the other hand, various improvements have been made to the cleanliness of the surface, particularly the prevention of adhesion of foreign matter, because it causes damage to the large glass substrate.

In order to increase the loading efficiency of the substrate, the substrate holding frame has been devised to be stacked at a high density. In the case of G6 (6th generation) size substrates, the frame interval is reduced to about 10 mm to 150 steps. In addition, even in G7.5 (7.5th generation) and G8 (8th generation) sizes, it has been studied to increase the number of stacked layers to increase the loading efficiency.

As the number of large, flexible substrates that can be flexibly stacked increases, the displacement of the substrate holding frame when the substrate holding frame is loaded or the displacement of the substrate holding frame due to the impact of transport after loading, etc. When taking out the substrate holding frame with the hand, handling failure or substrate damage may occur.

In addition, as described in Patent Document 1, it is necessary to press and adjust the multi-layered frames that are displaced by the impact of conveyance from the side and adjust the position completely. Position adjustment is difficult and the weight is heavy, so shifting the position may cause scratches and foreign matter.

The present invention has been completed through intensive research to solve such problems.

The first of the gist of the present invention to solve the above problems is
A rectangular frame in a plan view in which a pair of sides facing left and right and a pair of sides facing front and rear are connected, or the frame on which a substrate is placed is opposed to a pair of sides facing left and right. A frame transport device that is placed on an inner pallet that is rectangular in plan view with a pair of sides
The frame transport device
A robot hand unit for gripping the frame, a robot arm unit for holding and moving the robot hand unit, a robot hand unit and a robot control unit for controlling the operation of the robot arm unit;
The robot hand section
A height sensor A for detecting the height position of the frame or the inner pallet at one central portion in the left-right direction of at least one of the two front and rear sides of the frame or the inner pallet;
A lateral sensor B1 and a lateral sensor B2 for detecting a planar position in the left-right direction at two different positions in the front-rear direction of at least one of the left and right sides of the frame or the inner pallet;
A plane position in the front-rear direction at the corner of the frame or the inner pallet, and a vertical sensor C for detecting the height position of the frame or the inner pallet,
A frame transport device having a function of correcting the position and inclination of the robot hand unit based on position information detected by the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C. .

A second aspect of the present invention for solving the above problems is
The frame transport device according to claim 1, wherein the height sensor A is an ultrasonic sensor.

The third of the gist of the present invention for solving the above problems is as follows.
The frame transport device according to claim 1 or 2, wherein all of the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C are laser sensors.

The fourth of the gist of the present invention for solving the above problems is as follows.
The light sources of all of the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C are visible light semiconductor lasers.
It exists in the frame conveyance apparatus of the claim of any one of Claim 1 thru | or 3 characterized by the above-mentioned.

The fifth of the gist of the present invention for solving the above problems is as follows.
The frame transport device according to any one of claims 1 to 4, wherein the robot hand unit has a function of gripping a pair of sides facing the left and right sides of the frame. It is in.

The sixth of the gist of the present invention for solving the above problems is as follows.
The frame transport device according to any one of claims 1 to 5, wherein the robot hand unit has a function of aligning a pair of sides facing the front and rear of the frame. It is in.

The seventh of the gist of the present invention for solving the above problems is as follows.
The pair of sides facing the front and back of the frame body and the inner pallet are linear, and the pair of sides facing the left and right are curved. It exists in the frame conveying apparatus of Claim 1.

The eighth of the gist of the present invention for solving the above problems is
The height sensor A provided in the robot hand unit detects the height of the upper surface of the central part of at least one side before and after the inner pallet or the frame body placed on the inner pallet,
At a position where the robot hand portion does not contact the inner pallet or the frame placed on the inner pallet, the robot sensor is close to a distance that can be detected by the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C;
The horizontal sensor B1 and the horizontal sensor B2 detect position information on two planes having different positions in the front-rear direction of at least one of the left and right sides of the inner pallet or the frame placed on the inner pallet. And
In the corner portion where the longitudinal sensor C connects the front and rear sides and the left and right sides, the front and back positions on the plane of the inner pallet or the frame placed on the inner pallet and the height position of the upper surface are detected,
Based on the position information and height position information on the plane detected by the horizontal sensors B1 and B2 and the vertical sensor C, the position of the robot hand unit is corrected,
The robot hand holding the frame is lowered to the position of the inner pallet or the frame placed on the inner pallet, and the gripping frame is placed;
The frame body conveying method is characterized by the above.

The ninth of the gist of the present invention for solving the above problems is as follows.
The height sensor A provided in the robot hand unit detects the height of the upper surface of the central part of at least one side before and after the frame placed on the inner pallet,
At a position where the robot hand portion does not contact the inner pallet or the frame placed on the inner pallet, the robot sensor is close to a distance that can be detected by the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C;
The horizontal sensor B1 and the horizontal sensor B2 detect positions on two planes having different positions in the front-rear direction of at least one of the left and right sides of the inner pallet or a frame placed on the inner pallet,
In the corner portion where the longitudinal sensor C connects the front and rear sides and the left and right sides, the front and back positions on the plane of the inner pallet or the frame placed on the inner pallet and the height position of the upper surface are detected,
Based on the position information on the plane and the height position information detected by the horizontal sensors B1 and B2 and the vertical sensor C, the position of the robot hand unit is corrected,
The robot hand part is lowered to a position for gripping the frame placed on the inner pallet, and grips and removes the frame;
The frame body conveying method is characterized by the above.

The tenth aspect of the present invention for solving the above problems is as follows.
Based on the position information on the plane and the height position information detected by the horizontal sensors B1 and B2 and the vertical sensor C, the position of the robot hand unit is corrected for every certain number of steps,
Based on the height and the left and right positions and the front and rear positions of the robot hand unit that has performed the position correction,
Conveying the frame continuously while moving the position in the height direction of the robot hand unit based on the position information calculated by the number of steps of the frame;
It exists in the frame conveying method of Claim 8 or Claim 9 characterized by the above-mentioned.

The frame described in the claims is a frame for placing a substrate, and in the specification and drawings, it is also described as a substrate holding frame for the sake of clarity.
The front and rear and the left and right described in the claims are described in order to clarify the positional relationship of the four sides of the rectangular shape in plan view, and are specifically shown in FIGS.
The alphabets of the sensors described in the claims are also described for the sake of clarity in the description and drawings of A, B1, B2, and C.

Even when the loaded frame is displaced due to impact during transportation, the robot hand can correct the position of the frame to prevent a grip failure when taking out the frame. When the frames are gripped and stacked one by one, the positions of the frames are corrected and stacked, so that the accumulation of misalignment can be prevented. The grip failure of the body can be reduced, and the breakage of the substrate can also be reduced.

It is a figure which shows the robot hand part of a frame conveyance apparatus. It is a figure which shows the whole structure of a frame conveyance apparatus. It is a top view of a frame for substrate conveyance. It is sectional drawing which shows the state which mounts a board | substrate in the frame for board | substrate holding | maintenance. It is a perspective view which shows the state which mounts a board | substrate in the frame for board | substrate holding | maintenance. It is a perspective view which shows the state in which the board | substrate holding frame was mounted in the vibration proof pallet and the inner pallet, and was packed. It is a figure explaining the operation | movement which integrates this board | substrate holding frame body, after a frame body conveying apparatus conveys the board | substrate holding frame body, and mounted a board | substrate. It is a perspective view which shows the detection part of an inner pallet. It is a perspective view which shows the detection part of the laminated | stacked board | substrate conveyance frame. It is a figure which shows the operation | movement which the height sensor A of a frame conveyance apparatus detects the height position of a frame for board | substrate holding | maintenance. (A) It is a figure which shows the operation | movement which the horizontal sensor B1 of a frame conveyance apparatus detects the position of the left-right direction of a board | substrate holding frame. (B) It is a figure which shows the operation | movement in which the horizontal sensor B2 of a frame conveyance apparatus detects the position of the left-right direction of a board | substrate holding frame. (C) It is a figure which shows the inclination of the frame for board | substrate holding | maintenance confirmed from the detection information of horizontal sensor B1 and horizontal sensor B2 of a frame conveyance apparatus. (A) It is a figure which shows the operation | movement in which the vertical sensor C of the frame conveyance apparatus in this embodiment of this invention detects the position of the front-back direction of the frame for board | substrate holding | maintenance. (B) It is a figure which shows the operation | movement which the vertical sensor C of the frame conveying apparatus in this embodiment of this invention detects the height position of the frame for board | substrate holding | maintenance. (A) It is a figure which shows the case where a frame has shifted | deviated to the left-right direction. (B) It is a figure which shows the case where a frame body has shifted | deviated to the front-back direction. (C) It is a figure which shows the case where a frame is rotated centering around one place and shifted. (A) It is a figure explaining the relationship between the deviation | shift amount of the left-right direction of a frame, and a board | substrate edge part braking area | region. (B) It is a figure explaining the relationship between the deviation | shift amount of the front-back direction of a frame, and a board | substrate edge part braking area | region.

Before describing the frame transport apparatus 50 of the present embodiment of the present invention, (the configuration of the substrate holding frame 10 that holds the substrate and the method of holding the substrate by the frame) and (the substrate holding the substrate) The form in which frames are stacked and packed will be described.

(Configuration of the substrate holding frame 10 for holding the substrate and a method for holding the substrate by the frame)

FIG. 3, FIG. 4, FIG. 5 show the configuration of the substrate holding frame 10 used for storage and transportation by stacking large substrates of sixth generation substrates (1850 * 1500 mm) at high density and the holding method using the frame. It explains using.

As shown in FIG. 3, the substrate holding frame 10 includes a pair of metal frame members 11 a and 11 b facing left and right and a pair of metal frame members 11 c and 11 d facing front and rear connected by a corner piece 16. The metal frame portion 11 assembled in a rectangular shape in plan view is configured to have at least a substrate support plate 13 extending inward of the frame along the metal frame portion 11.

A fitting portion 12 is provided between the metal frame portion 11 and the substrate support plate 13 when the substrate holding frame body 10 is stacked up and down. The fitting portion 12 is not necessarily provided at this position. It is not necessary, and it is possible to provide the metal frame 11 or the corner piece 16.
The fitting portion 12 needs to be provided with a play that easily fits into the lower frame when stacking the frame bodies 10 and easily takes out from the lower frame body when taking out the frame body 10.

  However, if the amount of play is too large, the positional displacement between the frame bodies 10 increases, and the amount of displacement increases when stacked at a high density, which may cause defective gripping and conveyance of the frame body. It is important to make the minimum amount necessary.

A handle 15 for holding the substrate holding frame 10 by the robot hand 53 is provided outside the metal frame 11 of the substrate holding frame 10. The handle 15 is a part for the frame holding part 535 of the robot hand 53 to hold and transport the substrate holding frame 10 from the outside. Although not shown in the drawing, the substrate holding frame 10 does not necessarily have to be provided with the handle portion 15, and the substrate holding frame 10 can be held by an adsorption method.

FIG. 4 is a cross-sectional view taken along W1 and W2 on one of the left and right sides of the substrate holding frame 10 on which the substrate of FIG. 3 is placed, and shows a state where the substrates N1 and N2 are held.

A substrate is placed on the substrate support plate 13, and the substrate holding frame 10 is stacked and held and conveyed.
The substrate support member 13 is provided with the resin substrate holding member 14, and the substrate holding member 14 has a substrate holding portion 14 a on which the substrate is placed and a substrate end portion for controlling the left and right positions of the substrate. A brake unit 14c and a substrate vibration control unit 14b for controlling the vibration of the substrate are provided. The substrate holding member 14 is for preventing the substrate from coming into direct contact with the metal, preventing displacement of the left and right substrates, and suppressing vibration of the substrate.

The substrate vibration control unit 14b extends from the substrate end braking unit 14c to the inside of the substrate holding frame 10, and forms a gap with the upper surface of the peripheral portion of the substrate placed on the lower frame 10. A thick portion that is reduced to suppress vibrations, and a portion further from the thick portion further has a thinned portion with a larger gap between the upper surface of the substrate and the gap.

The substrate end braking region 14d is a region of the thick portion of the substrate vibration control unit 14b extending inward from the inner surface of the frame of the substrate end braking unit 14c, and the substrate end portion is located within the region. This is an area that needs to be held.
To safely hold or transport the board,
It is desirable that the substrates N1 and N2 are located inside the substrate end braking portion 14c provided in the metal frame 11, and the substrate end does not deviate from the substrate end braking region 14d.
FIG. 5 is a perspective view showing a relative positional relationship between the substrate holding frame 10 and the substrate N placed thereon.

(Form in which the frame holding the substrate is stacked and packed)

A form in which the frames holding the substrate are stacked and packed will be described with reference to FIG.

FIG. 6 is a view showing a state in which the substrate holding frames 10 on which the substrates are placed are stacked in multiple stages, placed on the inner pallet 62 and the anti-vibration pallet 61, and packed.
That is, the substrate holding frames 10 each having a single substrate placed thereon are stacked in multiple stages, the frame 10 on which the substrate is not placed is placed on the uppermost stage, and the upper lid 63 is mounted on the frame 10. In this state, the upper lid 63 and the inner pallet 62 are bound by the binding belt 64 and further placed on the vibration-proof pallet 61.
The frame 10 on which the uppermost substrate is not placed is the same frame as the substrate holding frame 10, and a space corresponding to one frame is provided between the upper lid 63 and the uppermost substrate. This is to avoid contact.
The number of steps of the substrate holding frame is 150 for the substrate holding frame on which the substrate is placed, and two steps of the frame 10 including the empty frame 10 and the upper lid 63 are placed. The total number of stages is 152.

The substrate holding frame 10 uses a metal material having structural strength for the frame member. This is because it is necessary to withstand the total load of the substrate holding frame 10 itself and the substrate N. For example, in the case of the sixth generation, one glass substrate is 5.1 kg, and the substrate holding frame is 5.5 kg. It is possible to stack the substrate holding frames in multiple stages at a high density, accommodate G6 size glass substrates, and stack up to 150 stages. The total weight when stacked in 150 stages is about 1.6 tons. Become.
The transport of the heavy-weight substrate holding frame 10 is generally performed by a robot.

Next, the operation of the frame transport apparatus 50 according to the present embodiment of the present invention (step of placing a substrate on the substrate holding frame 10) and (step of transporting and stacking the substrate holding frame 10) This will be described with reference to FIG.

(Process of placing a substrate on the substrate holding frame 10)

The upper lid 63 of the laminated body including the 152 stages of the substrate holding frame body 10 placed in the substrate holding frame body take-out section 80 of FIG. 7 is taken out by the frame body transport device 50A, and the substrate delivery apparatus 70 is transported to another predetermined place.
The upper lid 63 has an empty frame 10 on which a substrate is not placed after the substrate is placed on the 150-stage substrate holding frame body 10 and transferred to the substrate holding frame stacking unit 81. After being conveyed stepwise, it is placed on the top.

Thereafter, the 150-stage empty substrate holding frame 10 is taken out from the substrate holding frame take-out section 80 by the frame transfer device 50A, transferred to the substrate transfer device 70, and a substrate is placed thereon. The process will be described.

Hereinafter, it will be described in order from (Step 1) to (Step 7).

(Step 1) The substrate holding frame body 10 in which the empty substrate holding frame bodies 10 stacked in 150 stages are stacked in five stages from the upper surface of the substrate holding frame take-out portion 80 is transferred to the frame body. A step of horizontally placing the substrate 50A directly under the substrate transfer point of the substrate transfer device 70, in which the device 50A grips and moves and transfers the substrate to the substrate holding frame 10. In the present embodiment, the substrate holding frame 10 is gripped by five steps and conveyed to the substrate transfer device 70. However, the number of steps is not limited to five, but from the viewpoint of processing time and gripping stability. Determine the number of steps from.

(Step 2) The substrate is moved horizontally by the substrate transfer device 82 and stopped at the substrate transfer device 70, and all of the peripheral edges of the substrate are in the predetermined substrate edge braking region on the surface of the substrate holding member 14. Aligning to be included in 14d.

(Step 3) Although not shown in the figure, each pin is controlled to a height corresponding to the horizontal state or the bent state of the substrate by a plurality of pins protruding in the vertical direction from the gap of the substrate transfer device 70. And holding the substrate.

(Step 4) The frame body gripping portion 535 is obtained by using the frame body transporting device 50A having the plurality of frame body gripping portions 535 provided in the robot hand portion 53 as the handle portion 15 of the substrate holding frame body 10. The process of applying and crawling.

(Step 5) Although not shown in the drawing, the step of moving the substrate holding frame 10 upward in the vertical direction immediately below the substrate transfer device 70 to separate it from all the pins.

(Step 6) The substrate holding frame 10 is further moved upward in the vertical direction, the peripheral portion of the substrate is brought into contact with the surface of the substrate holding member 14, and the substrate is placed on the substrate holding frame 10. The process of mounting.

(Step 7) A step of transporting the substrate holding frame 10 on which the substrate is placed to the substrate holding frame stacking unit by the frame transporting device 50B.

The steps from Step 2 to Step 7 are repeated a plurality of times, and the substrate holding frame body 10 in the 150-stage substrate holding frame body take-out portion 80 is sequentially loaded with substrates.

In a state where all the five stages of the substrate holding frames 10 have been removed from the substrate transfer apparatus 70, the frame transfer apparatus 50A holds the next five stages of the substrate holding frames 10, and the substrate transfer apparatus 70. , The substrates are placed one by one on the substrate holding frame 10 and transferred.

Thereafter, the steps 1) to 7) are repeated.

  The above is the process of placing the substrate on the substrate holding frame 10, but the substrate holding frame 10 integrated in multiple stages may be misaligned due to impact of transportation, etc. When the frame transport device 50A grips the substrate holding frame 10, when the position correction is not performed, the handle 15 of the substrate holding frame 10 cannot be gripped due to the position shift, or the position shift In some cases, the substrate is placed in a state where there is a defect or misalignment in the substrate transfer device 70, and the substrate may be damaged by subsequent conveyance. The position correction will be described later.

Next, (the process of conveying and stacking the substrate holding frame 10) will be described.

  On the substrate holding frame 10 on which the substrate is placed, the substrate holding frame 10 obtained in the same manner is brought into surface contact with the front and back of the metal frame portion 11 of the substrate holding frame 10. It is a process of stacking.

Hereinafter, it will be described in order from (Step 8) to (Step 11).

(Step 8) The robot hand portion 53 of the frame transport apparatus 50B that holds the substrate holding frame body 10 on which the substrate is placed is placed directly above the substrate delivery apparatus 70 from the substrate holding frame body stacking section (substrate (Mounted) Step of moving directly above 81.

(Step 9) The robot hand portion 53 holding the substrate holding frame 10 moves downward in the vertical direction and is stacked on the inner pallet 62 in the substrate holding frame stacking portion (substrate mounted) 81 or previously. A step of bringing the metal frame portion 11 of the substrate holding frame 10 into contact with the metal frame portion 11 of the obtained substrate holding frame 10 (substrate mounted).

(Step 10) The robot hand portion 53 holding the substrate holding frame 10 is moved further downward in the vertical direction to completely move the substrate holding frame 10 to the inner pallet 62 or the substrate holding frame 10. The process of stacking on top.

(Step 11) The frame gripping portion 535 of the robot hand portion 53 provided in the frame transport device 50B is removed from the substrate holding frame 10 and moved upward in the vertical direction for the next step. The process of waiting.

The steps 8) to 11) are repeated, and the substrate holding frame 10 is stacked on the substrate holding frame stacking unit 81. Since the positional deviation increases between 10, when the substrate holding frame 10 is stacked in a plurality of stages, the position of the substrate holding frame 10 is provided in the robot hand unit 53 of the frame transfer device 50B. A position correction step for detecting the position by the position detection sensor and correcting the position is introduced to prevent the occurrence of a conveyance failure.

Next, the above-described (position correction step introduction frequency) will be described.

A specific effect of introducing the position correcting step is that even if a position shift occurs in the 150-stage multi-stage substrate holding frame, it is possible to prevent poor gripping when the board holding frame is taken out. In addition, since the substrate holding frame body is gripped and placed on the substrate transfer device with little displacement, the entire periphery of the substrate is placed in the substrate end braking region 14d on the surface of the substrate holding member 10. As included, the robot hand unit 53 of the frame transport apparatus 50A having the plurality of frame gripping portions 535 can be aligned at a predetermined position, and damage to the substrate is prevented even in subsequent transport. There is something you can do.

The reason why the position correction process is introduced every certain number of stages is to shorten the processing time for transporting a series of substrate holding frames 10.

The frequency of the position correction is an accumulation when the frames 10 are stacked in a plurality of stages, assuming that each frame is shifted by the maximum play amount when the frames 10 are stacked in a plurality of stages. It is preferable that the frequency of the position correction be performed with the number of steps that does not deviate from the substrate edge braking region 14d at the substrate edge.

The figure schematically shows how the frame body 10 is shifted by one stage. FIG. 13a shows a case of shifting in the left-right direction, FIG. 13b shows a case of shifting in the front-rear direction, and FIG. 13c shows a case of shifting by rotating around one place. The amount of shift for each stage is preferably within the amount of play between frames.

The amount of play between the upper and lower frames of the substrate holding frame 10 of the present embodiment of the present invention is L1 mm in the short side direction, that is, the left-right direction, and L2 mm in the long side direction, that is, the front-rear direction. The amount of shift in the short side direction in a state where the frames 10 are stacked in 150 stages is L1 × 150 mm, and L2 × 150 mm in the long side direction.

14A and 14B are views for explaining the relationship between the shift amount of the frame body 10 and the substrate end braking region 14d.
In the present embodiment, the substrate edge braking region 14d is 4.25 mm, L1 is 0.13 mm, and L2 is 0.2 mm. The frequency of position correction will be described with reference to FIGS. 14a and 14b.
In any case, it is a diagram showing the number of steps in which the frame 10 is stacked and accumulated and the amount of deviation does not exceed the substrate end braking region 14d, that is, 4.25 mm.

As shown in FIG. 14a, in the left-right direction of the frame body 10, since the cumulative shift amount when 22 layers are stacked exceeds 4.25 mm, it is necessary to perform position correction up to 21 steps. In the front-rear direction, as shown in FIG. 14b, since the cumulative displacement amount exceeds 4.25 mm at the 33rd stage, it is necessary to perform position correction by the 32nd stage. In order to safely transport the frame body 10 in both the left-right direction and the front-rear direction, it is necessary to correct at least once within 21 steps.

From the results described above, the frequency of introducing the position correction step is preferably less than 21 stages in consideration of transport safety and processing time.
As described above, by introducing the position correction step for every fixed number of steps, the substrate holding frame 10 can be integrated without causing a large positional shift even when stacked in as many as 150 steps.

  The frequency of performing position correction according to the present invention is determined by the amount of play when the substrate edge braking region 14d and the frame 10 are overlapped, and the frequency F of position correction is not limited to the above-described embodiment. The optimal frequency is determined by Equation 1.

F is the frequency (number of steps) of position correction,
14d is a board | substrate edge part braking area | region of the frame 10 for board | substrate holding | maintenance,
L is the amount of play per stage when the substrate transport frame 10 is vertically stacked, and is the larger of the play amount L1 in the left-right direction and the play amount L2 in the front-rear direction. .

Next, (the overall configuration of the frame transport device 50) and (the configuration of the robot hand unit 53) according to the present embodiment of the present invention will be described.

(Overall configuration of frame transport device 50)

The overall configuration of the frame transport apparatus 50 will be described with reference to FIG.

The frame transport device 50 includes the robot hand unit 53 that grips the substrate holding frame 10, the robot arm 52 that supports and moves the robot hand unit 53, the robot hand unit 53, and the robot arm 52. At least the robot control unit 51 for controlling the operation is provided.
The robot hand unit 53 is provided with a substrate holding frame for carrying out position control for gripping and taking out the substrate holding frame 10 from the integrated substrate holding frame 10 or a substrate holding frame placed thereon. A detection sensor for performing position control for gripping and stacking at a predetermined place is provided.

FIG. 2A is a diagram illustrating a state in which the substrate holding frame 10 having four straight sides is gripped.

FIG. 2B is a diagram illustrating a state in which the substrate holding frame 10 in which a pair of opposite sides are curved and another pair of opposite sides is linear is gripped.
In both the substrate holding frame 10 having straight sides and the substrate holding frame 10 having a pair of opposing sides curved, the robot hand portion to be handled can have the same configuration. Hereinafter, the handling of the frame 10 having a pair of sides curved will be mainly described.

(Configuration of robot hand unit 53)

A configuration of the robot hand unit 53 provided in the frame transport apparatus 50 will be described with reference to FIG.

  FIG. 1 is a plan view of the robot hand unit 53 that holds the substrate holding frame 10 that holds a G6 size glass substrate.

The robot hand portion 53 is connected to the robot arm portion 52 and an arm connection portion 538, and the portion where the robot hand portion 53 holds the substrate holding frame 10 is composed of four sides. A hand frame body 530 and a reinforcing bar 537 are provided as a skeleton.

The height sensor A that measures the distance to the substrate holding frame 10 is provided at the center of at least one side of the front and back sides of the hand frame 530, and both sides of the front and back sides of the substrate frame 530 An alignment portion 536 that aligns the positions in the front-rear direction is provided.

Since the height sensor A first needs to detect the height position of the substrate holding frame 10 from a long distance with a rough accuracy, the ultrasonic sensor KEYENCE manufactured by KEYENCE has a relatively wide detection range of 150 mm to 700 mm. FW-07 is attached.

On the two left and right sides of the hand frame 530, frame gripping portions 535 for gripping the substrate holding frame 10 are provided at three locations, one on each of the left and right sides.

Further, at least one of the left and right sides of the hand frame 530 is provided with a horizontal sensor B1 and a horizontal sensor B2 for detecting the position of the substrate holding frame 10 in the horizontal direction.

Further, a vertical sensor C for detecting the position in the front-rear direction and the height position of the substrate holding frame 10 is provided at the corner portion of the hand frame 530.
The horizontal sensors B1 and B2 and the vertical sensor C need to detect the height of the frame 10 for holding the substrate roughly with the height sensor A and accurately detect it from a point close to about 140 mm. LV-S31, a KEYENCE laser sensor, which uses a visible light semiconductor laser having a detection distance as short as 50 mm to 200 mm but high detection accuracy, was used.

  At the center of the hand frame 530, an arm connecting part 538 connected to the robot arm part is provided, and the robot hand part 53 is moved to a predetermined position based on the detection information.

Next, in the present embodiment of the present invention (the part for detecting the positions of the substrate holding frame 10 and the inner pallet 62) and (the position detection method and the position correction method of the frame transport apparatus 50), the sixth generation This will be described using a substrate holding frame 10 that can be laminated with a high density of 150 glass substrates.

(A part for detecting the positions of the substrate holding frame 10 and the inner pallet 62)

  A portion where the frame transport device 50 detects the positions of the substrate holding frame 10 and the inner pallet 62 will be described with reference to FIGS. 8 and 9B.

  FIG. 9B shows a state in which the substrate holding frame 10 in which a pair of opposing sides are curved and the other opposing pair of sides is linear is stacked on the inner pallet 62 up to six levels. Further, the frame body 10 is further stacked thereon to form a 150-stage integrated body as a whole.

The height sensor A provided in the robot hand unit 53 detects the height detection unit a at the lowest position in the center of one of the pair of sides that are curved and opposed. That is, the height detection part a of the inner pallet 62 in FIG. 8 or the height detection part a of the substrate holding frame 10 in FIG. 9B is detected.

The horizontal sensors B1 and B2 provided in the robot hand unit 53 respectively detect the horizontal detection units b1 and b2 at different positions on a pair of opposite sides in a straight line. That is, the horizontal detection unit b1 and the horizontal detection unit b2 of the inner pallet 62 in FIG. 8 or the horizontal detection unit b1 and the horizontal detection unit b2 of the substrate holding frame 10 in FIG. 9B are detected.

The vertical sensor C provided in the robot hand unit 53 includes a vertical detection unit c1 at a corner where a pair of sides that are linearly opposed to one side of a pair of sides that are curved and opposed to each other and a height of the vertical sensor C1. The length detection unit c2 is detected. That is, the vertical detection unit c1 and the height detection unit c2 of the inner pallet 62 in FIG. 8 or the vertical detection unit c1 and the height detection unit c2 of the substrate holding frame 10 in FIG. 9B are detected.

  FIG. 9A shows a state in which the substrate holding frame 10 having a rectangular shape in plan view in which all the two pairs of sides are linear is stacked on the inner pallet 62, and the frame 10 is further formed thereon. Stacked to form a 150-stage aggregate as a whole. The positions of the detection portions of the frame 10 are all linear, but the same position as the frame including a pair of curved sides in FIG. 9B is preferable. This is because even if the sides are straight, there is a possibility of being affected by bending or the like, and the position can be measured most stably.

(Position detection method and position correction method of frame transport device 50)

A position detection method and a position correction method of the frame body conveyance device 50 will be described with reference to FIGS.
FIGS. 10 to 12 are plan views showing the position detection unit of the inner pallet and the substrate holding frame, and are diagrams for explaining the detecting operation.

  First, as shown in FIG. 10, the robot hand portion 53 is lowered from above, and the height sensor A detects the height detection portion a of the inner pallet 62 or the substrate holding frame 10, and the robot hand portion 53. Is lowered by −Z with respect to the set value, then rises again by + Z, then descends again, confirms the height of the set value, and stops at a predetermined height. In the present embodiment, this height needs to be measured with high accuracy next to the distance between the inner pallet 62 or the substrate holding frame 10, and is within the detection range of the horizontal sensor and vertical sensor of the laser sensor. It was set to a certain 140 mm.

  Next, as shown in FIG. 11, the robot hand portion 53 moves in the left-right direction, and the lateral sensor B1 and the lateral sensor B2 are metal in the lateral detection portions b1 and b2 of the inner pallet 62 and the substrate holding frame 10. The position of the outer edge of the frame part 11 is detected. FIG. 11a shows the horizontal detector b1, and FIG. 11b shows the horizontal detector b2.

  FIG. 11c shows the inclination θ of the substrate holding frame 10 with respect to the robot hand unit 53, which is confirmed from the positions of the horizontal detection parts b1 and b2 detected by the horizontal sensor B1 and the horizontal sensor B2.

  Next, as shown in FIG. 12 a, the robot hand portion 53 moves in the front-rear direction, and the vertical sensor C is positioned at the outer edge in the front-rear direction of the inner pallet 62 and the metal frame portion 11 of the substrate holding frame 10. The vertical detection unit c1 is detected.

  Next, as shown in FIG. 12 b, the robot hand portion 53 moves up and down, and the height sensor C is a height detection that is a corner portion of the inner pallet 62 and the metal frame portion 11 of the substrate holding frame 10. The part c2 is detected.

An embodiment of a substrate holding frame that is used for storage, transportation, and the like by stacking large-size substrates of sixth generation substrates (1850 * 1500 mm) with high density will be described.
The weight of a sixth generation substrate (1850 * 1500 mm) with a thickness of 0.7 mm is about 5.0 kg, and is a substrate holding frame for holding the sixth generation substrate shown in FIG. The metal frame portions 11c and 11d have a curved shape, the height h shown in FIG. 4 is 10 mm, and the weight of the aluminum substrate holding frame 10 having a thickness of 2 mm is 5.5 kg. The total weight with the substrate held was 10.5 kg.

The board edge braking area 14d of the frame 10 was 4.25 mm, and the play amount L between the frames was 0.2 mm.

A stack in which the empty substrate holding frames 10 are stacked in 150 stages is placed on the substrate holding frame take-out portion 80 shown in FIG. 7, and the position is corrected by the uppermost frame 10 in the 150 stages. The five-stage frame 10 including the frame body 10 is gripped by the robot hand unit 53 of the frame body transfer apparatus 50A and transferred to the substrate transfer apparatus 70. In the substrate transfer apparatus 70, the first-stage frame body 10 is transferred. A single substrate was placed on the frame 10, and the frame 10 was transferred to the substrate holding frame stacking unit 81. Substrates were similarly placed on the remaining four stages of the frame body 10 of the substrate transfer apparatus 70, transported to the substrate holding frame body accumulation unit 81, and stacked.

The next five steps of the frame 10 placed on the substrate holding frame take-out unit 80 are gripped by the robot hand unit 53 and transferred to the substrate transfer device 70, and one substrate is placed on the frame 10. Thereafter, the frame body 10 was transported to the substrate holding frame body accumulation unit 81. In the substrate transfer device 70, one substrate was placed on the one-stage frame 10, and the frame 10 was transported to the substrate holding frame stacking unit 81.

Similarly, the substrates were placed on the remaining four-stage frame bodies of the substrate transfer apparatus 70, transported to the substrate holding frame body accumulation unit 81, and stacked.

The next frame 10 placed in the substrate holding frame take-out unit 80 is conveyed from the substrate holding frame take-out unit 80 by the same operation every five stages, and the substrate is placed in the substrate transfer unit 70. It was conveyed to the board | substrate holding | maintenance frame integration | stacking part 81 with the frame conveyance apparatus 50B, and was piled up.

The 150 stages of the frame body 10 of the substrate holding frame body take-out part is taken out 5 stages at a time, and a series of operations is repeated four times. After 20 stages in total are taken out, the next 21st stage of the frame body 10 is used as the frame body. The position of the transfer device 50A was corrected.

Similarly, every time the frame body 10 of the substrate holding frame take-out portion is conveyed 20 stages, position correction is performed on the next frame body 10.

  On the other hand, in the substrate holding frame stacking unit 81, the position of the robot hand unit 53 of the frame transport apparatus 50B is corrected every time the frame 10 on which the substrate is placed is stacked 20 times.

In the above-described operation, the substrate is placed on the frame body 10 using the frame body transport device 50, stacked in 150 stages on the substrate holding frame body stacking portion 81, and covered with the upper lid 63 as shown in FIG. Then, the upper lid 63 and the inner pallet 62 were fixed, and the package was placed on the anti-vibration pallet 61 as the package 60.

It was confirmed that the package 60 was unpacked after the package 60 was transported, the substrate was taken out, and it was continuously used for safe practical use. There was no problem of gripping failure or substrate damage due to the displacement of the frame 10 placed on the substrate holding frame take-out portion 80.

Similarly to Example 1, a large substrate of a sixth generation substrate (1850 * 1500 mm) and the frame body 10 were used in the same stage as shown in FIG. Were taken out in 5 stages, and 20 stages were taken out in total, and then the position of the frame transport apparatus 50A was corrected with the next frame.

The board edge braking region 14d of the frame 10 was 4.50 mm, and the play amount L between the frames was 0.3 mm.
Subsequently, after the frame body 10 of the substrate holding frame take-out portion was conveyed 14 stages, the position of the frame body 10 at the next 15th stage was corrected.

  On the other hand, also in the substrate holding frame stacking unit 81, the position of the robot hand unit 53 of the frame transport apparatus 50B is corrected for each state in which the frame 10 on which the substrate is placed is stacked in 15 stages.

In the above-described operation, the substrate is placed on the frame body 10 using the frame body transport device 50, stacked in 150 stages on the substrate holding frame body stacking portion 81, and covered with the upper lid 63 as shown in FIG. Then, the upper lid 63 and the inner pallet 62 were fixed, and the package was placed on the anti-vibration pallet 61 as the package 60.

It was confirmed that the package 60 was unpacked after the package 60 was transported, the substrate was taken out, and it was continuously used for safe practical use. There was no problem of gripping failure or substrate damage due to the displacement of the frame 10 placed on the substrate holding frame take-out portion 80.

Similarly to Example 1, a large substrate of a sixth generation substrate (1850 * 1500 mm) and the frame body 10 were used in the same stage as shown in FIG. Were taken out in five stages, and a total of 25 stages were taken out, and then the position of the frame body conveyance device 50A was corrected with the next frame body.

The board edge braking region 14d of the frame 10 was 5.00 mm, and the play amount L between the frames was 0.2 mm.
Subsequently, after the frame 10 of the substrate holding frame take-out portion was transported 23 stages, position correction was performed on the next frame 24 of the 24th stage.

  On the other hand, in the substrate holding frame stacking unit 81, the position of the robot hand unit 53 of the frame transport apparatus 50B is corrected for each state in which the frame 10 on which the substrate is placed is stacked 24 times.

In the above-described operation, the substrate is placed on the frame body 10 using the frame body transport device 50, stacked in 150 stages on the substrate holding frame body stacking portion 81, and covered with the upper lid 63 as shown in FIG. Then, the upper lid 63 and the inner pallet 62 were fixed, and the package was placed on the anti-vibration pallet 61 as the package 60.

It was confirmed that the package 60 was unpacked after the package 60 was transported, the substrate was taken out, and it was continuously used for safe practical use. There was no problem of gripping failure or substrate damage due to the displacement of the frame 10 placed on the substrate holding frame take-out portion 80.

The present invention relates to a substrate carrying method in which one rigid rectangular substrate is horizontally placed on a substrate holding frame and conveyed or stored in a state where a plurality of the substrate holding frames are stacked. It can be used for transporting and storing plate-like objects such as glass, metal, silicon, and plastic, various members for flat display panels, solar cell panels, lighting panels, and intermediate products.

10 Substrate holding frame (frame)
DESCRIPTION OF SYMBOLS 11 Metal frame part, Metal frame material 11a, 11b Left and right metal frame part, Metal frame material 11c, 11d Metal frame part before and behind, Metal frame material 12 Fitting part 13 Substrate support plate 14 Substrate holding member 14a Substrate holding part 14b Substrate Vibration Control Unit 14c Substrate Edge Braking Unit 14d Substrate Edge Braking Area 15 Handle 16 Corner Piece 50 Frame Conveying Device 50A Frame Conveying Device 50B Frame Conveying Device 51 Robot Control Unit 52 Robot Arm Unit 53 Robot Hand Unit 530 Hand frame A Height sensor A
B1 Side sensor B1
B2 Side sensor B2
C Vertical sensor C
535 Frame body gripping part 536 Positioning part 537 Crosspiece 538 Arm connection part 60 Packing body 61 Anti-vibration pallet 62 Inner pallet a Height detection part a
b1 Horizontal detector b1
b2 Horizontal detector b2
c1 Vertical detector c1
c2 Height detector c2
63 Upper lid 64 Binding belt 70 Substrate delivery device 80 Substrate holding frame take-out unit 81 Substrate holding frame stacking unit 82 Substrate transport device N, N1, N2 Substrate K Openings L, L1, L2 Playing of substrate holding frame amount

Claims (10)

A rectangular frame in a plan view in which a pair of sides facing left and right and a pair of sides facing front and rear are connected, or the frame on which a substrate is placed is opposed to a pair of sides facing left and right. A frame transport device that is placed on an inner pallet that is rectangular in plan view with a pair of sides
The frame transport device
A robot hand unit for gripping the frame, a robot arm unit for holding and moving the robot hand unit, a robot hand unit and a robot control unit for controlling the operation of the robot arm unit;
The robot hand section
A height sensor A for detecting the height position of the frame or the inner pallet at one central portion in the left-right direction of at least one of the two front and rear sides of the frame or the inner pallet;
A lateral sensor B1 and a lateral sensor B2 for detecting a planar position in the left-right direction at two different positions in the front-rear direction of at least one of the left and right sides of the frame or the inner pallet;
A plane position in the front-rear direction at the corner of the frame or the inner pallet, and a vertical sensor C for detecting the height position of the frame or the inner pallet,
A frame transport apparatus comprising a function of correcting the position and inclination of the robot hand unit based on position information detected by the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C. The frame conveyance device according to claim 1, wherein the height sensor A is an ultrasonic sensor. The frame transport apparatus according to claim 1 or 2, wherein all of the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C are laser sensors. The light sources of all of the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C are visible light semiconductor lasers.
The frame transport apparatus according to any one of claims 1 to 3, wherein the frame transport apparatus is characterized in that 5. The frame transport apparatus according to claim 1, wherein the robot hand unit has a function of gripping a pair of sides facing the left and right of the frame. 6. The frame transport apparatus according to claim 1, wherein the robot hand unit has a function of aligning a pair of sides facing the front and back of the frame. The pair of sides facing the front and back of the frame body and the inner pallet are linear, and the pair of sides facing the left and right are curved. The frame conveying apparatus of Claim 1. The height sensor A provided in the robot hand unit detects the height of the upper surface of the central part of at least one side before and after the inner pallet or the frame body placed on the inner pallet,
At a position where the robot hand portion does not contact the inner pallet or the frame placed on the inner pallet, the robot sensor is close to a distance that can be detected by the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C;
The horizontal sensor B1 and the horizontal sensor B2 detect position information on two planes having different positions in the front-rear direction of at least one of the left and right sides of the inner pallet or the frame placed on the inner pallet. And
In the corner portion where the longitudinal sensor C connects the front and rear sides and the left and right sides, the front and back positions on the plane of the inner pallet or the frame placed on the inner pallet and the height position of the upper surface are detected,
Based on the position information and height position information on the plane detected by the horizontal sensors B1 and B2 and the vertical sensor C, the position of the robot hand unit is corrected,
The robot hand holding the frame is lowered to the position of the inner pallet or the frame placed on the inner pallet, and the gripping frame is placed;
A frame conveying method characterized by the above. The height sensor A provided in the robot hand unit detects the height of the upper surface of the central part of at least one side before and after the frame placed on the inner pallet,
At a position where the robot hand portion does not contact the inner pallet or the frame placed on the inner pallet, the robot sensor is close to a distance that can be detected by the horizontal sensor B1, the horizontal sensor B2, and the vertical sensor C;
The horizontal sensor B1 and the horizontal sensor B2 detect positions on two planes having different positions in the front-rear direction of at least one of the left and right sides of the inner pallet or a frame placed on the inner pallet,
In the corner portion where the longitudinal sensor C connects the front and rear sides and the left and right sides, the front and back positions on the plane of the inner pallet or the frame placed on the inner pallet and the height position of the upper surface are detected,
Based on the position information on the plane and the height position information detected by the horizontal sensors B1 and B2 and the vertical sensor C, the position of the robot hand unit is corrected,
The robot hand part is lowered to a position for gripping the frame placed on the inner pallet, and grips and removes the frame;
A frame conveying method characterized by the above. Based on the position information on the plane and the height position information detected by the horizontal sensors B1 and B2 and the vertical sensor C, the position of the robot hand unit is corrected for every certain number of steps,
Based on the height and the left and right positions and the front and rear positions of the robot hand unit that has performed the position correction,
Conveying the frame continuously while moving the position in the height direction of the robot hand unit based on the position information calculated by the number of steps of the frame;
The frame transport method according to claim 8 or 9, wherein:

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