CN213651176U - High-efficient glass storage ware - Google Patents

Abstract

The utility model provides a high-efficient glass accumulator, including frame and circulation storage device, utilize circulation storage device's glass horizontal migration roller subassembly, circulation lift connecting piece, glass lifter and take the structure cooperation of self-locking function's glass vertical circulation conveying power supply to form between the glass lifter and store the removal layer with glass board unloading to glass horizontal migration roller subassembly or glass board up storage usefulness. The synchronism is high, can realize storing the glass board or the unloading conveying high-efficiently, and stability is high, has self-locking function, and the buffer memory is effectual, guarantees again that the conveying is accurate, protects the glass board effectively.

Description

High-efficient glass storage ware

Technical Field

The utility model relates to a technical field of glass production, a high-efficient glass accumulator specifically says so.

Background

At present, the hollow glass is high-efficiency compartment heat-insulating glass manufactured by bonding two or more pieces of glass with an aluminum alloy frame containing a drying agent by using a high-strength airtight composite bonding agent. Because various performances of the hollow glass are superior to those of common double-layer glass, the hollow glass is widely applied to occasions needing indoor air conditioning, such as houses, restaurants, hotels, office buildings, schools, hospitals, shops and the like, and can also be used for doors and windows of trains, automobiles, ships, refrigerated cabinets and the like.

In the glass production line, glass plates are conveyed from the production line to a glass storage device for glass caching or glass is conveyed from the glass storage device to the production line for glass subsequent processing according to production requirements.

However, the existing glass memory has the following disadvantages in practical use:

1. high precision of the fit between the glass storage and the transfer table of the production line is required, otherwise the glass sheet can be damaged.

2. Only one glass plate can be stored or fed one by one, so that the speed is low, and the production efficiency is reduced.

3. The glass plate has poor storage or blanking synchronism, and the surface of the glass plate is easy to scratch.

4. Glass sheet is at unloading or storage in-process, and the conveying power supply of traditional glass memory does not have drive self-locking function, reduces stability, influences conveying efficiency, is difficult to satisfy the demand of glass production line.

Disclosure of Invention

An object of the utility model is to overcome prior art not enough, provide a high-efficient glass accumulator, its synchronism is high, can realize storing the glass board or unloading conveying high-efficiently, and stability is high, has self-locking function, and the buffer memory is effectual, guarantees again that the conveying is accurate, protects the glass board effectively.

The invention aims to realize the following steps: a high-efficiency glass storage device comprises a frame and a circulating storage device arranged on the frame, wherein the circulating storage device comprises a glass horizontal moving roller wheel assembly, a circulating lifting connecting piece, a glass lifting rod and a glass longitudinal circulating transmission power source with a self-locking function,

the glass horizontal moving roller component is installed at the bottom of the rack, the glass longitudinal circulating transmission power source is installed at the top of the rack, the output end of the glass longitudinal circulating transmission power source is meshed with one end of a circulating lifting connecting piece, the circulating lifting connecting piece is longitudinally distributed on the left side and the right side of the glass horizontal moving roller component, the glass lifting rods are longitudinally distributed on the circulating lifting connecting piece, glass inserting holes for enabling the glass lifting rods to ascend and descend relative to the glass horizontal moving roller component are formed in the circulating lifting connecting piece, and two ends of the glass lifting rods are installed in the glass inserting holes respectively, so that a glass storage moving layer for enabling glass plates to be discharged to the glass horizontal moving roller component or upwards stored is formed between the glass lifting rods.

Optimized according to the above, the glass longitudinal circulating transmission power source comprises a servo motor, a worm gear speed reducer, an upper driven gear, a lower driven gear and a transverse linkage rod, the worm gear speed reducer,

the worm and gear speed reducer is installed at the top of the rack, an output shaft of the servo motor is connected with an input end of the worm and gear speed reducer, an output end of the worm and gear speed reducer is connected with an input end of the upper driven gear through the transverse linkage rod, the upper driven gear and the lower driven gear are installed at the upper end and the lower end of two sides of the rack respectively, and the circulating lifting connecting piece is connected with the upper driven gear and the lower driven gear in a meshed mode respectively.

According to the optimization, the four worm and gear speed reducers are arranged on the top of the rack and are respectively distributed at equal intervals, the longitudinal linkage rods are respectively connected between the worm and gear speed reducers, the input end of the servo motor is connected with the worm and gear speed reducer, and the upper driven gear is symmetrically arranged with the corresponding worm and gear speed reducer.

According to the optimization, the glass horizontal moving roller assembly is provided with a glass monitor for detecting the glass plate, and the glass monitor is in signal connection with the servo motor.

According to the optimization, the circulating lifting connecting piece is provided with a plurality of glass jacks which are longitudinally distributed at equal intervals, and two ends of a plurality of glass lifting rods are respectively matched and buckled with the glass jacks so as to form a plurality of layers of glass storage moving layers which are longitudinally distributed.

According to the optimization, the circulating lifting connecting piece is a U-shaped chain.

According to the optimization, the horizontal plane of the glass horizontal moving roller component is lower than the inner horizontal plane of the discharged glass storage moving layer.

Or the horizontal plane of the glass horizontal moving roller wheel assembly is consistent with the inner horizontal plane of the corresponding glass storage moving layer.

The utility model has the advantages that: adopt the high-efficient glass storage of this structure, during the operation, the vertical circulation conveying power source of glass drives the circulation lift connecting piece rotation, makes the glass lifter synchronous lift to the realization is stored the glass board from glass horizontal migration roller subassembly and is moved the layer or store the glass board from glass and move the layer unloading to glass horizontal migration roller subassembly with glass board storage. The synchronism is high, promotes stability, has self-locking function, and the buffer memory is effectual, guarantees again that the conveying is accurate, protects the glass board effectively.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of the present invention.

Fig. 2 is a top view of the preferred embodiment of the present invention.

Fig. 3 is a cross-sectional view of the preferred embodiment of the present invention.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

As shown in the attached drawings 1 to 3, the high-efficiency glass storage device of the present invention comprises a frame 1 and a circulating storage device installed on the frame 1. The circulating storage device comprises a glass horizontal moving roller wheel assembly 2, a circulating lifting connecting piece 3, a glass lifting rod 4 and a glass longitudinal circulating transmission power source with a self-locking function. The glass horizontal moving roller wheel assembly 2 is installed at the bottom of the rack 1, the glass longitudinal circulating transmission power source is installed at the top of the rack 1, and the output end of the glass longitudinal circulating transmission power source is meshed and connected with one end of the circulating lifting connecting piece 3. The glass horizontal movement roller component is characterized in that the circulation lifting connecting pieces 3 are longitudinally distributed on the left side and the right side of the glass horizontal movement roller component 2, the glass lifting rods 4 are longitudinally distributed on the circulation lifting connecting pieces 3, the circulation lifting connecting pieces 3 are provided with glass insertion holes 5 for enabling the glass lifting rods 4 to lift up and down relative to the glass horizontal movement roller component 2, and two ends of the glass lifting rods 4 are respectively installed in the glass insertion holes 5, so that glass plates are fed to the glass horizontal movement roller component 2 or a glass storage moving layer 6 for upwards storing the glass plates is formed between the glass lifting rods 4.

That is, during the operation, the glass is longitudinally and circularly transmitted to the power source to drive the circular lifting connecting piece 3 to rotate, and the glass lifting rod 4 is lifted along with the power source, so that the glass storage moving layer 6 is lifted or lowered, and the glass plate is stored in the glass storage moving layer 6 from the glass horizontal moving roller component 2 or is discharged to the glass horizontal moving roller component 2 from the glass storage moving layer 6. The synchronism is high, promotes stability, has self-locking function, and the buffer memory is effectual, guarantees again that the conveying is accurate, protects the glass board effectively.

Referring to fig. 1 to 3, the glass longitudinal circulating transmission power source comprises a servo motor 7, a worm gear speed reducer 8, an upper driven gear 9, a lower driven gear 10, a transverse linkage rod 11, and the worm gear speed reducer 8. The worm and gear speed reducer 8 is installed at the top of the rack 1, the output shaft of the servo motor 7 is connected with the input end of the worm and gear speed reducer 8, and the output end of the worm and gear speed reducer 8 is connected with the input end of the upper driven gear 9 through the transverse linkage rod 11. The upper driven gear 9 and the lower driven gear 10 are respectively installed at the upper end and the lower end of two sides of the frame 1, and the circulating lifting connecting piece 3 is respectively meshed with the upper driven gear 9 and the lower driven gear 10.

In practical application, the four worm and gear speed reducers 8 are arranged at the top of the rack 1 and are respectively distributed at equal intervals, and the longitudinal linkage rods 12 are respectively connected between the worm and gear speed reducers 8. The input end of the servo motor 7 is connected with a worm gear speed reducer 8, and the upper driven gear 9 and the corresponding worm gear speed reducer 8 are symmetrically arranged. The structural stability is improved, the running synchronism of the longitudinal linkage rod 12 is enhanced, and the glass plate is prevented from being damaged.

Further, a glass monitor 13 for detecting a glass plate is attached to the glass horizontal movement roller assembly 2, and the glass monitor 13 is signal-connected to the servo motor 7. Structural stability promotes the precision that detects the glass board, ensures the production demand of glass board.

Referring to fig. 1 to 3, the circulating lifting connector 3 is provided with a plurality of glass insertion holes 5 which are longitudinally distributed at equal intervals, and two ends of a plurality of glass lifting rods 4 are respectively matched and buckled with the glass insertion holes 5 to form a plurality of glass storage moving layers 6 which are longitudinally distributed. The assembly is convenient, and the structural stability is enhanced.

In addition, the horizontal plane of the glass horizontal moving roller assembly 2 is lower than the inner horizontal plane of the discharged glass storage moving layer 6. Or the horizontal plane of the glass horizontal moving roller assembly 2 is consistent with the inner horizontal plane of the corresponding glass storage moving layer 6.

When the glass sheet is conveyed to a designated position along with the glass horizontally moving roller assembly 2, the glass monitor 13 transmits relevant information to the glass longitudinal circulation transmission power source in real time. The servo motor 7 of the glass longitudinal circulating transmission power source operates to drive the four worm and gear speed reducers 8 to synchronously rotate under the linkage of the longitudinal linkage rod 12 and the transverse linkage rod 11, the upper driven gear 9 and the lower driven gear 10 synchronously rotate along with the four worm and gear speed reducers, so that the four circulating connecting pieces synchronously and circularly rotate, and the glass lifting rods 4 arranged horizontally at each layer are driven to ascend and contact with the glass plates. The glass plates enter the glass storage moving layer 6 and ascend with the glass plates, so that the glass plates are stored in the glass storage device layer by layer.

According to production requirements, when glass plates in a glass storage device are to be discharged to a conveying production line, a glass horizontal moving roller assembly 2 operates, the glass is conveyed to a power source to move in a longitudinal circulating mode, a servo motor 7 operates, four worm and gear speed reducers 8 are driven to rotate synchronously under the linkage of a longitudinal linkage rod 12 and a transverse linkage rod 11, an upper driven gear 9 and a lower driven gear 10 rotate synchronously along with the rotation, four circulating connecting pieces rotate synchronously and circularly, and therefore glass lifting rods 4 arranged horizontally are driven to descend, and the glass plates descend along with the rotation. When the glass lifting rod 4 is lowered to the same level with the glass horizontal moving roller component 2 or lower than the level of the glass horizontal moving roller component 2, the glass plate touches the glass horizontal moving roller component 2, the glass monitor 13 transmits the relevant information to the glass longitudinal circulating transmission power source in real time, the glass longitudinal circulating transmission power source is suspended, and after a certain time, the glass longitudinal circulating transmission power source continues to work. When the glass monitor 13 can not detect the glass, the glass longitudinal circulating transmission power source stops working, so that the glass plates are blanked layer by layer and transmitted outwards.

During, under the structural cooperation of the servo motor 7, the worm gear speed reducer 8, the longitudinal linkage rod 12 and the transverse linkage rod 11, the glass plate buffer memory device is high in synchronism, high in stability, good in glass plate buffer memory effect, accurate in transmission and effective in protection of glass plates.

The above-mentioned embodiment is only the utility model discloses the better embodiment of effect, all with the utility model discloses a high-efficient glass storage device is the same or the structure of equivalence, all is in the utility model discloses a protection within range.

Claims (8)

1. The utility model provides a high-efficient glass storage ware, includes frame (1) and installs the circulation storage device on frame (1), its characterized in that: the circulating storage device comprises a glass horizontal moving roller wheel assembly (2), a circulating lifting connecting piece (3), a glass lifting rod (4) and a glass longitudinal circulating transmission power source with a self-locking function,

the glass horizontal moving roller wheel assembly (2) is arranged at the bottom of the frame (1), the glass longitudinal circulating transmission power source is arranged at the top of the frame (1), the output end of the glass longitudinal circulating transmission power source is meshed and connected with one end of a circulating lifting connecting piece (3), the circulating lifting connecting piece (3) is longitudinally distributed on the left side and the right side of the glass horizontal moving roller component (2), the glass lifting rods (4) are longitudinally distributed on the circulating lifting connecting piece (3), the circulating lifting connecting piece (3) is provided with a glass jack (5) for enabling the glass lifting rod (4) to move up and down relative to the glass horizontal moving roller wheel assembly (2), two ends of the glass lifting rod (4) are respectively arranged in the glass jacks (5), so that a glass storage moving layer (6) for discharging the glass plate to the glass horizontal moving roller assembly (2) or storing the glass plate upwards is formed between the glass lifting rods (4).

2. The high efficiency glass reservoir of claim 1, wherein: the glass longitudinal circulating transmission power source comprises a servo motor (7), a worm gear speed reducer (8), an upper driven gear (9), a lower driven gear (10) and a transverse linkage rod (11), the worm gear speed reducer (8),

the worm and gear speed reducer (8) is installed at the top of the rack (1), the output shaft of the servo motor (7) is connected with the input end of the worm and gear speed reducer (8), the output end of the worm and gear speed reducer (8) is connected with the input end of the upper driven gear (9) through the transverse linkage rod (11), the upper driven gear (9) and the lower driven gear (10) are installed at the upper end and the lower end of the two sides of the rack (1) respectively, and the circulating lifting connecting piece (3) is meshed with the upper driven gear (9) and the lower driven gear (10) respectively.

3. The high efficiency glass reservoir of claim 2, wherein: the four worm and gear speed reducers (8) are arranged at the top of the rack (1) at equal intervals, longitudinal linkage rods (12) are connected between the worm and gear speed reducers (8), the input end of the servo motor (7) is connected with the worm and gear speed reducers (8) in the servo motor, and the upper driven gear (9) and the corresponding worm and gear speed reducers (8) are symmetrically arranged.

4. The high efficiency glass reservoir of claim 3, wherein: the glass horizontal moving roller component (2) is provided with a glass monitor (13) for detecting the glass plate, and the glass monitor (13) is in signal connection with the servo motor (7).

5. The high efficiency glass reservoir of claim 1, wherein: the circulating lifting connecting piece (3) is provided with a plurality of glass jacks (5) which are longitudinally distributed at equal intervals, and two ends of a plurality of glass lifting rods (4) are respectively matched and buckled with the glass jacks (5) to form a multi-layer longitudinally-distributed glass storage moving layer (6).

6. The high efficiency glass reservoir of claim 1, wherein: the circulating lifting connecting piece (3) is a U-shaped chain.

7. The high efficiency glass reservoir of claim 1, wherein: the horizontal plane of the glass horizontal moving roller component (2) is lower than the inner horizontal plane of the blanking glass storage moving layer (6).

8. The high efficiency glass reservoir of claim 1, wherein: the horizontal plane of the glass horizontal moving roller wheel assembly (2) is consistent with the inner horizontal plane of the corresponding glass storage moving layer (6).

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