CN112456147A - Be applied to rotatory switching-over device of jumbo size glass substrate jacking - Google Patents

Abstract

The invention discloses a jacking rotary reversing device applied to a large-size glass substrate, which comprises a driving rotary component, a lifting component and a frame working component, wherein the driving rotary component consists of a frame plate, a rotary in-place detection module, a connecting flange, an RV (right volume) reducer and a rotary servo motor, the lifting component consists of a lifting in-place detection module, a synchronous lifter, a box-type ball unit, a lifting reducer and a lifting servo motor, and the frame working component consists of a carbon fiber frame and a grid frame The matching efficiency between upstream and downstream equipment is low.

Description

Be applied to rotatory switching-over device of jumbo size glass substrate jacking

Technical Field

The invention relates to the technical field of glass substrate production, in particular to a jacking rotary reversing device applied to a large-size glass substrate.

Background

At present, with the development of large-size display equipment, the market has an increasing demand for large-size liquid crystal glass panels, a large number of conveying devices are needed in the production process of the large-size liquid crystal glass panels, the large-size glass substrates need to be reversed at +/-90 degrees and +/-180 degrees in cooperation with the demand of clients for the production process of the liquid crystal glass panels, and meanwhile, the operation space of client field equipment needs to be considered, the functional integration is improved as far as possible, the production efficiency is improved, and the implementation cost is reduced.

According to the above, in the existing liquid crystal glass panel production process, a six-axis robot is used for realizing glass reversing, or a self-made reversing arm can be adopted when the glass substrate on a roller conveying line is small. However, with the increase of the size of the glass panel and the urgent attention on the production space and the production efficiency, the existing conveying equipment is continuously exposed in the two aspects, and the problems that the large-size glass cannot be applied, the panel production space is not reasonably utilized, and the matching efficiency between the upstream equipment and the downstream equipment is low are solved.

Therefore, social production needs a large-size glass substrate +/-90 DEG +/-180 DEG reversing device which can reasonably utilize production space so as to improve production efficiency and is matched with a roller conveying line, so that the existing problems are solved.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the reversing device applied to the large-size glass substrate jacking and rotating reversing is used for reversing +/-90 DEG and +/-180 DEG on a roller conveying line, so that the problem of a plurality of technical defects at present is solved.

In order to solve the technical problems, the technical scheme of the invention is as follows: the utility model provides a be applied to rotatory switching-over device of jumbo size glass substrate jacking, includes drive rotating assembly, lifting unit and frame work subassembly, drive rotating assembly by frame plate, rotatory detection module that targets in place, flange, RV speed reducer and rotatory servo motor constitute, lifting unit by go up and down to target in place detection module, synchronous riser, box ball unit, lifting speed reducer and lift servo motor and constitute, frame work subassembly constitute by carbon fiber frame and net rack, lifting unit set firmly on drive rotating assembly, frame work subassembly set firmly on drive rotating assembly, just frame work subassembly and lifting unit adopt welded connection, the rotation detection module that targets in place set firmly in frame plate one side, the rotation detection module that targets in place adopt bolted connection with the frame plate, just the rotation detection module that targets in place adopt the signal of telecommunication line connection with rotatory servo motor, the connecting flange is rotatably connected with the frame plate, the RV reducer is fixedly arranged at the bottom of the connecting flange, the RV reducer is connected with the connecting flange through a bolt, the RV reducer is connected with the frame plate through a bolt, the rotary servo motor is fixedly arranged at the bottom of the frame plate, the rotary servo motor is connected with the frame plate through a bolt, the rotary servo motor is connected with the RV reducer through a coupler, the lifting in-place detection module is fixedly arranged at the middle end of the side wall of the frame plate, the lifting in-place detection module is connected with the frame plate through a bolt, the lifting in-place detection module is connected with the lifting servo motor through an electric signal line, the synchronous lifters are fixedly arranged around the bottom of the frame plate, and the synchronous lifters are connected with the frame plate through bolts, the box-type ball units are fixedly arranged at two sides of the bottom of the frame plate, the box-type ball units are connected with the frame plate by bolts, the box-type ball unit is meshed with the synchronous lifter by adopting gear teeth, the lifting speed reducer is fixedly arranged at the bottom of the frame plate and is connected with the frame plate by adopting bolts, the lifting speed reducer is connected with the synchronous lifter by a coupler, the lifting servo motor is fixedly arranged at the bottom of the frame plate and is connected with the frame plate by bolts, the lifting servo motor is connected with the lifting speed reducer by adopting a coupler, the number of the carbon fiber frames is four, the carbon fiber frames are distributed on the top of the connecting flange and are movably connected with the connecting flange, the grid frame is fixedly arranged at the top of the carbon fiber frame, and the grid frame is connected with the carbon fiber frame in a welding mode.

Further, frame plate bottom still set firmly the strengthening rib of a plurality of quantity, strengthening rib and frame plate adopt welded connection, just the strengthening rib adopt welded connection each other, frame plate inside still be equipped with the mounting hole of a plurality of quantities, the mounting hole be circular through-hole.

Furthermore, the top of the connecting flange is fixedly provided with a reinforcing plate, the reinforcing plate is connected with the connecting flange in a welding manner, and the reinforcing plate is connected with the carbon fiber frame in a welding manner.

Further, the rotation arrival detection module detects the rotation angle of the connecting flange, the rotation arrival detection module detects the forward 90-degree rotation and the reverse 90-degree rotation of the connecting flange, and the rotation arrival detection module triggers the rotation servo motor to stop after detecting that the connecting flange rotates forward and backward by 90 degrees.

Further, the lifting in-place detection module detects the lifting height of the carbon fiber frame, the detection lifting range of the lifting in-place detection module is 0-10mm, and the lifting in-place detection module triggers the lifting servo motor to stop after the carbon fiber frame is lifted up and down to be close to the induction range.

Furthermore, the carbon fiber frame comprises an outer fixing frame and an inner adjusting frame, the inner adjusting frame is fixedly arranged in the outer fixing frame, and the inner adjusting frame is connected with the outer fixing frame through bolts.

Further, the grid frame top still set firmly and prevent the static silica gel strip, prevent that static silica gel strip and grid frame adopt the adhesive to be connected.

Compared with the prior art, the rotary reversing device applied to the jacking of the large-size glass substrate has the following advantages:

1. by adopting the integrated structure below the roller conveying line, the integrated structure has the advantages of extremely small occupied equipment space, greatly shortened action beat and effectively improved equipment production efficiency.

2. The combination of the servo motor and the RV reducer is adopted, so that the running stability and the angle positioning precision are improved, and the interference problem caused by the retraction of the frame working assembly below the roller conveying surface is avoided.

3. Because the lifting assembly adopts a mutually matched structure of the lifting servo motor, the lifting speed reducer and the synchronous lifter, the effective positioning of the lifting stroke can be realized, the structure is compact, the reliability is high, and the lifting assembly is assisted by a box type ball unit, so that the shaking caused by the matching of racks in the synchronous lifter can be eliminated, and the torque impact generated when the frame working assembly rotates can be effectively counteracted;

(4) the frame work assembly main part adopts the carbon fiber pipe to constitute, light in weight, and intensity is high, warp for a short time, and the anti-static silica gel strip structure of installation on the carbon fiber can prevent that glass from producing static and improves the production yield, can prevent effectively that the displacement from taking place when jumbo size glass commutates to saved the regular structure of centre gripping, the equipment manufacturing cost that significantly reduces simplifies equipment and constitutes, improve equipment stability, the reliability.

(5) The driving rotating assembly consists of a rotating in-place detection module, an RV reducer and a rotating servo motor, so that unidirectional or reciprocating rotation is facilitated, 90-degree and 180-degree rotating stroke limiting is realized, and different process requirements are met.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a side view of a rotary reversing device for lifting a large-sized glass substrate;

FIG. 2 is a front view of a rotary reversing device for lifting a large-sized glass substrate;

FIG. 3 is a perspective view of a rotary reversing device for lifting a large-sized glass substrate 1;

FIG. 4 is an enlarged perspective view of part A of a rotary reversing device for lifting a large-sized glass substrate;

FIG. 5 is a perspective view of a rotary reversing device for lifting a large-sized glass substrate;

FIG. 6 is an enlarged cross-sectional view of the external fixation frame and the internal adjustment frame;

FIG. 7 is a perspective view showing the fitting state of the apparatus to a conventional roller conveyor line;

fig. 8 is a plan view showing the state of fitting the apparatus to a conventional roller conveyor line.

The device comprises a driving rotating assembly 1, a lifting assembly 2, a frame working assembly 3, a frame plate 4, a rotation in-place detection module 5, a connecting flange 6, an RV reducer 7, a rotation servo motor 8, a lifting in-place detection module 9, a synchronous lifter 10, a box type ball unit 11, a lifting reducer 12, a lifting servo motor 13, a carbon fiber frame 14, a grid frame 15, reinforcing ribs 401, mounting holes 402, a reinforcing plate 601, an outer fixing frame 1401, an inner adjusting frame 1402 and an anti-static silica gel strip 1501.

The following detailed description will be further described in conjunction with the above-identified drawings.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the concepts underlying the described embodiments, however, it will be apparent to one skilled in the art that the described embodiments may be practiced without some or all of these specific details, and in other cases well-known process steps have not been described in detail.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the invention.

As shown in fig. 1, 2, 3, 4, 5, 6, 7, 8, a rotary reversing device for lifting a large-sized glass substrate comprises a driving rotary component 1, a lifting component 2, a frame working component 3, a frame plate 4, a rotation in-place detection module 5, a connecting flange 6, an RV reducer 7, a rotary servo motor 8, a lifting in-place detection module 9, a synchronous lifter 10, a box-type ball unit 11, a lifting reducer 12, a lifting servo motor 13, a carbon fiber frame 14, and a grid frame 15, wherein the lifting component 2 is fixedly arranged on the driving rotary component 1, the frame working component 3 and the lifting component 2 are connected by welding, the rotation in-place detection module 5 is fixedly arranged on one side of the frame plate 4, the rotation in-place detection module 5 is connected with the frame plate 4 by bolts, and the rotation in-place detection module 5 is connected with the rotary servo motor 8 by an electric signal line, the connecting flange 6 is rotatably arranged at the upper end inside the frame plate 4, the connecting flange 6 is rotatably connected with the frame plate 4, the RV reducer 7 is fixedly arranged at the bottom of the connecting flange 6, the RV reducer 7 is connected with the connecting flange 6 by a bolt, the RV reducer 7 is connected with the frame plate 4 by a bolt, the rotary servo motor 8 is fixedly arranged at the bottom of the frame plate 4, the rotary servo motor 8 is connected with the frame plate 4 by a bolt, the rotary servo motor 8 is connected with the RV reducer 7 by a coupler, the lifting in-place detection module 9 is fixedly arranged at the middle end of the side wall of the frame plate 4, the lifting in-place detection module 9 is connected with the frame plate 4 by a bolt, and the lifting in-place detection module 9 is connected with the lifting servo motor 13 by an electric signal line, the synchronous lifter 10 is fixedly arranged around the bottom of the frame plate 4, the synchronous lifter 10 is connected with the frame plate 4 through bolts, the box-type ball units 11 are fixedly arranged on two sides of the bottom of the frame plate 4, the box-type ball units 11 are connected with the frame plate 4 through bolts, the box-type ball units 11 are connected with the synchronous lifter 10 through gear teeth in a meshed manner, the lifting reducer 12 is fixedly arranged at the bottom of the frame plate 4, the lifting reducer 12 is connected with the frame plate 4 through bolts, the lifting reducer 12 is connected with the synchronous lifter 10 through a coupler, the lifting servo motor 13 is fixedly arranged at the bottom of the frame plate 4, the lifting servo motor 13 is connected with the frame plate 4 through bolts, the lifting servo motor 13 is connected with the lifting reducer 12 through a coupler, and the carbon fiber frames 14 are four in number, the carbon fiber frames 14 are distributed on the top of the connecting flange 6, the carbon fiber frames 14 are movably connected with the connecting flange 6, the grid frame 15 is fixedly arranged on the top of the carbon fiber frames 14, and the grid frame 15 is connected with the carbon fiber frames 14 in a welding mode;

the large-size glass substrate jacking rotary reversing device has the following functions;

A. when the driving rotating assembly 1 and the lifting assembly 2 are not started, the frame working assembly 3 is at the initial position of the lifting position, the upper surface of the anti-static silica gel strip 1501 is 10mm away from the existing conveying surface, and at the moment, the driving rotating assembly 1 and the lifting assembly 2 are hidden under the existing roller conveying line (not marked), so that interference cannot occur when large-size glass (not marked) flows through;

B. when large-size glass (not marked) needs to turn over above the driving rotating assembly 1 and the lifting assembly 2, the lifting servo motor 13 rotates to enable the lifting speed reducer 12 to drive the synchronous lifter 10 to move upwards to jack up the large-size glass (not marked), when the lifting in-place detection module 9 detects that the carbon fiber frame 14 is in place, the edge of the lower part of the carbon fiber frame 14 is more than 20mm away from the conveying surface, the rotating servo motor 8 starts to drive the RV speed reducer 7 to rotate at the moment, the rotating motion is transmitted to the carbon fiber frame 14 through the connecting flange 6, so that the reversing of the large-size glass (not marked) is realized, the rotating in-place detection module 5 detects the rotating in-place condition of the rechecked large-size glass (not marked), the positive and negative 90 degrees of the large-size glass (not marked) can be realized, namely, the limiting and positive and negative switching rotation within the range of 180 degrees are realized, the lifting servo motor 13 rotates reversely, so that the lifting speed reducer 12 drives the synchronous lifter 10 to move downwards, large-size glass (not marked) falls on an existing roller conveying line (not marked) along with the carbon fiber frame 14, the carbon fiber frame 14 continuously descends, when the carbon fiber frame 14 is detected to be in place by the lifting in-place detection module 9, the upper surface of the anti-static silica gel strip 1501 is 10mm away from the conveying surface, the driving rotating assembly 1 and the lifting assembly 2 are hidden under the existing roller conveying line (not marked), and the existing roller conveying line (not marked) can convey the large-size glass (not marked) to the next station;

the bottom of the frame plate 4 is fixedly provided with a plurality of reinforcing ribs 401, the reinforcing ribs 401 are connected with the frame plate 4 in a welding manner, the reinforcing ribs 401 are mutually connected in a welding manner, a plurality of mounting holes 402 are arranged in the frame plate 4, and the mounting holes 402 are circular through holes;

it should be noted that the reinforcing rib 401 is used for enhancing the strength of the frame plate 4 and improving the operation stability of the components mounted thereon, and the mounting hole 402 can be conveniently in bolt butt joint with an external mounting equipment carrier (not labeled);

the top of the connecting flange 6 is also fixedly provided with a reinforcing plate 601, the reinforcing plate 601 is connected with the connecting flange 6 in a welding manner, and the reinforcing plate 601 is connected with the carbon fiber frame 14 in a welding manner;

it should be noted that the reinforcing plate 601 can butt-joint the connecting flange 6 and the carbon fiber frame 14, so that the carbon fiber frame 14 can drive the large-size glass (not labeled) at the top to synchronously rotate along with the connecting flange 6;

the rotation in-place detection module 5 detects the rotation angle of the connecting flange 6, the rotation in-place detection module 5 detects the forward 90-degree rotation and the reverse 90-degree rotation of the connecting flange 6, and the rotation in-place detection module 5 triggers the rotation servo motor 8 to stop after detecting that the connecting flange 6 rotates forward and backward 90 degrees;

the rotation position detection module 5 can trigger the rotation servo motor 8 to stop after the connecting flange 6 rotates to the detection position, namely, the positive 90-degree and reverse 90-degree rotation limiting is realized, namely, the 180-degree rotation of large-size glass is met;

the in-place lifting detection module 9 detects the lifting height of the carbon fiber frame 14, the detection lifting range of the in-place lifting detection module 9 is 0-10mm, and the in-place lifting detection module 9 triggers the lifting servo motor 13 to stop after the carbon fiber frame 14 is lifted up and down to approach the induction range;

it should be noted that the in-place lifting detection module 9 can trigger the lifting servo motor 13 to stop after the lifting height of the carbon fiber frame 14 reaches the detection range, so as to achieve the purpose of limiting the lifting height of the carbon fiber frame 14;

the carbon fiber frame 14 consists of an outer fixing frame 1401 and an inner adjusting frame 1402, the inner adjusting frame 1402 is fixedly arranged in the outer fixing frame 1401, and the inner adjusting frame 1402 is connected with the outer fixing frame 1401 by bolts;

it should be noted that the inner adjusting frame 1402 can be inserted into the outer fixing frame 1401, the telescopic lengths of the outer fixing frame 1401 and the inner adjusting frame 1402 can be pulled according to needs, and then the outer fixing frame 1401 and the inner adjusting frame 1402 can be fixed through bolts, so that the structure is convenient for targeted regulation and control according to the requirements of large-size glass (not marked) or production processes;

the top of the grid frame 15 is also fixedly provided with an anti-static silica gel strip 1501, and the anti-static silica gel strip 1501 is connected with the grid frame 15 by adopting an adhesive;

it should be noted that the anti-static silica gel strip 1501 can prevent large-size glass (not marked) from being in hard contact with the grid frame 15, so as to protect the large-size glass (not marked), and meanwhile, the large-size glass (not marked) can be conveniently adsorbed on the anti-static silica gel strip 1501, so that the glass is effectively prevented from generating static electricity, the production yield is improved, and the subsequent rotation and lifting operation is facilitated.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (7)

1. The utility model provides a be applied to rotatory switching-over device of jumbo size glass substrate jacking, its characterized in that includes drive rotating assembly, lifting unit and frame work subassembly, drive rotating assembly constitute by frame board, rotatory detection module that targets in place, flange, RV speed reducer and rotatory servo motor, lifting unit by go up and down to target in place detection module, synchronous riser, box ball unit, lifting speed reducer and lift servo motor and constitute, frame work subassembly constitute by carbon fiber frame and net frame, lifting unit set firmly on drive rotating assembly, frame work subassembly set firmly on drive rotating assembly, and frame work subassembly and lifting unit adopt welded connection, the rotatory detection module that targets in place set firmly in frame board one side, just the rotatory detection module that targets in place and rotatory servo motor adopt the signal of telecommunication line connection, the connecting flange is rotatably arranged at the inner upper end of the frame plate, the RV reducer is fixedly arranged at the bottom of the connecting flange and is connected with the frame plate, the rotary servo motor is fixedly arranged at the bottom of the frame plate and is connected with the RV reducer by a coupling, the lifting in-place detection module is fixedly arranged at the middle end of the side wall of the frame plate, the lifting in-place detection module is connected with the lifting servo motor by an electric signal wire, the synchronous lifter is fixedly arranged at the periphery of the bottom of the frame plate, the box-type ball units are fixedly arranged at two sides of the bottom of the frame plate, the box-type ball units and the synchronous lifter are connected by gear teeth in a meshing manner, the lifting reducer is fixedly arranged at the bottom of the frame plate and is connected with the synchronous lifter by a coupling, and the lifting servo motor is fixedly arranged at the bottom of the frame plate, and the lifting servo motor is connected with the lifting speed reducer by adopting a coupler, the number of the carbon fiber frames is four, the carbon fiber frames are distributed at the top of the connecting flange, and the grid frame is fixedly arranged at the top of the carbon fiber frames.

2. The apparatus according to claim 1, wherein a plurality of ribs are fixedly disposed at the bottom of the frame plate, the ribs are welded to each other, and a plurality of mounting holes are disposed in the frame plate.

3. The device according to claim 1, wherein a reinforcing plate is fixedly arranged on the top of the connecting flange, and the reinforcing plate is welded to the carbon fiber frame.

4. The apparatus according to claim 1, wherein the rotation-to-position detection module detects a rotation angle of the flange, and the rotation-to-position detection module detects a 90 ° rotation of the flange and triggers the rotation servo motor to stop.

5. The apparatus according to claim 1, wherein the lift-to-position detection module detects a lift height of the carbon fiber frame, and the lift-to-position detection module triggers the lift servo motor to stop when the carbon fiber frame is lifted up and down to approach an induction range.

6. The apparatus according to claim 1, wherein the carbon fiber frame comprises an outer frame and an inner frame, and the inner frame is fixed inside the outer frame.

7. The apparatus according to claim 1, wherein an anti-static silicone strip is further secured to the top of the grid frame.

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