CN215324865U - Intelligent storage equipment for electronic devices - Google Patents

Abstract

The intelligent storage equipment for the electronic devices comprises a part box, a conveying part and a storage part, wherein RFID tags are attached to the periphery of the part box; the conveying part comprises a base, and a feeding conveying belt is arranged at the top end of the base; a scanning box is arranged on the side part of the feeding conveying belt; the end part of the feeding conveyer belt is connected with a lifting mechanism, and the lifting mechanism is connected with a steering mechanism; the inventory part comprises a transfer conveying belt, and one end of the transfer conveying belt is connected with a lifting mechanism; the other end of the transfer conveyer belt is connected with a stacking mechanism, and the stacking mechanism is arranged in the container; the container is separated by a partition plate; a plurality of paper labels are attached to the surface of the partition board. According to the part box, different storage spaces are designed according to the sizes of the parts, the space utilization rate of the part box is improved, a plurality of groups of containers are adopted according to the types of the parts, the container management is more standard, the labor intensity is reduced, and the working efficiency is improved.

Description

Intelligent storage equipment for electronic devices

Technical Field

The utility model belongs to the technical field of storage, and particularly relates to intelligent storage equipment for electronic devices.

Background

The logistics storage is to store, keep, load, unload, transport and deliver goods by utilizing self-built or leased storehouses and fields; traditional warehouse definitions are given from the perspective of material reserves.

At present, for the management work of product in and out of an electrical appliance industry, the manual work is mainly adopted to carry out the work of product retrieval, goods taking, delivery, classification, filing and warehousing. However, the traditional warehouse management method has certain limitations for the electronic component industry. Because the electronic products are various in types and large in quantity, the storage land area is enlarged and the storage cost is increased by adopting the traditional storage mode; the efficiency of products entering and exiting the warehouse is reduced, the working strength of workers is enhanced, and the labor cost is increased; and the problems of unclear accounts and objects and the like occur.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model provides an intelligent storage device for electronic devices, which has the following specific technical scheme:

the intelligent storage equipment for the electronic devices comprises a part box, a conveying part and a storage part, wherein RFID tags are attached to the periphery of the part box;

the conveying part comprises a base, and a feeding conveying belt is arranged at the top end of the base; a scanning box is arranged on the side part of the feeding conveying belt, and an RFID label reader-writer is arranged in the scanning box; the RFID label reader-writer is used for reading the information of the RFID label; the end part of the feeding conveyer belt is connected with a lifting mechanism, and the lifting mechanism is connected with a steering mechanism;

the inventory part comprises a transfer conveying belt, and one end of the transfer conveying belt is connected with a lifting mechanism; the other end of the transfer conveyer belt is connected with a stacking mechanism, and the stacking mechanism is arranged in the container; the stacking mechanism is used for storing the part boxes in the container, and the container is separated by a supporting plate; a plurality of paper labels are attached to the surface of the supporting plate.

Furthermore, one or more partition plates are arranged inside the part box, and the part box is equally divided into a plurality of cavities by the partition plates.

Furthermore, the lifting mechanism comprises a first lifting piece and a second lifting piece which are symmetrically arranged and have the same structure, the first lifting piece comprises a first roller wheel, a tray, a chain wheel, a support, a second roller wheel and a motor, the first roller wheel and the second roller wheel are connected through the chain wheel, and the tray is distributed on the surface of the chain wheel; the first roller and the second roller are fixed through a support, and the second roller is connected with a motor.

Furthermore, the cross-section of tray adopts "L" font structure, just equidistance distributes between the tray.

Further, the steering mechanism comprises a baffle, a second pneumatic sliding block, a second pneumatic sliding rail, a third hydraulic telescopic rod and a push plate, the second pneumatic sliding rail is mounted on the side portion of the support, and the side portion of the second pneumatic sliding rail is connected with the second pneumatic sliding block in a sliding mode; a baffle is fixed on the side part of the second pneumatic sliding block, and a third hydraulic telescopic rod is fixed on the side part of the baffle; and a push plate is fixed on the side part of the third hydraulic telescopic rod.

Furthermore, at least two containers are arranged and are communicated with each other through a stacking mechanism; the containers are equally divided into a plurality of areas by supporting plates.

Furthermore, the stacking mechanism comprises a first pneumatic sliding block, a first hydraulic telescopic rod, a cross rod, a clamping plate, a pull rod, a second hydraulic telescopic rod and a first pneumatic sliding rail, wherein the top end of each area is provided with the first pneumatic sliding rail, and the bottom end of the first pneumatic sliding rail is connected with the first pneumatic sliding block in a sliding manner; a first hydraulic telescopic rod is mounted at the bottom end of the first pneumatic sliding block, and a cross rod is fixed at the bottom end of the first hydraulic telescopic rod; a second hydraulic telescopic rod is initially fixed in the bottom end of the cross rod, and clamping plates are rotatably connected to two sides of the bottom end of the cross rod; the center of the clamping plate is rotatably connected with a pull rod, and the top end of the pull rod is rotatably connected with the bottom end of the second hydraulic telescopic rod.

The utility model has the beneficial effects that: the warehousing equipment manually puts parts into the part boxes, and then controls a mechanical structure through industrial software to put the part boxes into the container for storage, so that warehousing work is realized; when goods are taken, the part box can be sent to a goods taking station under the control of industrial control software; according to the part box, different storage spaces are designed according to the sizes of parts, the space utilization rate of the part box is improved, multiple groups of containers are adopted according to the types of the parts, the container management is more standard, the parts can be delivered into and taken out of the warehouse by operating an industrial computer, the labor intensity is reduced, and the working efficiency is improved.

Drawings

Fig. 1 is a schematic diagram illustrating an overall structure of an electronic device intelligent warehousing equipment;

FIG. 2 shows a schematic structural view of the lift mechanism of the present invention;

FIG. 3 shows a schematic of the stacking mechanism of the present invention;

FIG. 4 shows a schematic structural view of the steering mechanism of the present invention;

FIG. 5 shows a schematic structural view of the partitionless parts box of the present invention;

FIG. 6 is a schematic view showing the construction of the parts box of the present invention having two partitions;

FIG. 7 shows a schematic of the construction of the parts box of the present invention having six dividers;

FIG. 8 is a block diagram showing the schematic structure of the working principle of the present invention;

shown in the figure: 1. the container, 11, a supporting plate, 12, a paper label, 2, a base, 21, a feeding conveying belt, 3, a transfer conveying belt, 4, a stacking mechanism, 41, a first pneumatic slide block, 42, a first hydraulic telescopic rod, 43, a cross rod, 44, a clamping plate, 45, a pull rod, 46, a second hydraulic telescopic rod, 47, a first pneumatic slide rail, 5, a steering mechanism, 51, a baffle, 52, a second pneumatic slide block, 53, a second pneumatic slide rail, 54, a third hydraulic telescopic rod, 55, a push plate, 6, a part box, 61, an RFID label, 62, a baffle, 7, 813, 8, a lifting mechanism, 81, a first lifting piece, 811, a first roller, 812, a tray, an industrial personal computer, a chain wheel, 814, a support, 815, a second roller, 816, a motor, 82, a second lifting piece, 9 and a scanning box.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

The intelligent storage equipment for the electronic devices comprises a part box 6, a conveying part and a storage part, wherein RFID tags 61 are attached to the periphery of the part box 6, and relevant data in the part box 6 are recorded through the RFID tags 61;

the conveying part comprises a base 2, and a feeding conveying belt 21 is arranged at the top end of the base 2; a scanning box 9 is arranged on the side part of the feeding conveyer belt 21, and an RFID label reader-writer is arranged in the scanning box 9; the RFID tag reader-writer is used for reading the information of the RFID tag 61; the end part of the feeding conveyer belt 21 is connected with a lifting mechanism 8, and the lifting mechanism 8 is connected with a steering mechanism 5;

the inventory part comprises a transfer conveyer belt 3, and one end of the transfer conveyer belt 3 is connected with a lifting mechanism 8; the other end of the transfer conveyer belt 3 is connected with a stacking mechanism 4, and the stacking mechanism 4 is arranged in the container 1; the stacking mechanism 4 is used for storing the part boxes 6 in the container 1, and the container 1 is separated by a supporting plate 11; a plurality of paper labels 12 are attached to the surface of the supporting plate 11; the parts are stored, and the parts are convenient to enter and exit from the warehouse.

As an improvement of the above technical solution, one or more partition plates 62 are arranged inside the parts box 6, and the parts box 6 is equally divided into a plurality of cavities by the partition plates 62; different storage spaces are designed for the part boxes 6 according to the sizes of parts, the space utilization rate of the part boxes 6 is improved, multiple groups of containers 1 are adopted according to the types of the parts, the management of the containers 1 is more standard, and the warehouse entry and exit work of the parts can be completed through an operator control machine 7 (an industrial computer), so that the labor intensity is reduced, and the working efficiency is improved. And the database access data management is carried out through management software, so that the clear account and article are ensured.

As an improvement of the above technical solution, the lifting mechanism 8 includes a first lifting member 81 and a second lifting member 82 which are symmetrically arranged and have the same structure, and the first lifting member 81 includes a first roller 811, a tray 812, a sprocket 813, a bracket 814, a second roller 815 and a motor 816, the first roller 811 and the second roller 815 are connected by the sprocket 813, and the tray 812 is distributed on the surface of the sprocket 813; the first roller 811 and the second roller 815 are fixed by a bracket 814, and the second roller 815 is connected with a motor 816; the realization goes up and down to the part goods.

As an improvement of the technical scheme, the cross section of the tray 812 adopts an L-shaped structure, and the trays 812 are distributed at equal intervals.

As an improvement of the above technical solution, the steering mechanism 5 includes a baffle 51, a second pneumatic slide block 52, a second pneumatic slide rail 53, a third hydraulic telescopic rod 54 and a push plate 55, the second pneumatic slide rail 53 is mounted at a side portion of the bracket 814, and the side portion of the second pneumatic slide rail 53 is slidably connected to the second pneumatic slide block 52; a baffle plate 51 is fixed on the side part of the second pneumatic slide block 52, and a third hydraulic telescopic rod 54 is fixed on the side part of the baffle plate 51; a push plate 55 is fixed on the side of the third hydraulic telescopic rod 54.

As an improvement of the technical scheme, at least two containers 1 are arranged, and the containers 1 are communicated through a stacking mechanism 4; the containers 1 are equally divided into a plurality of areas by supporting plates 11; multiple groups of containers are adopted according to the types of parts, and the container management is more standard.

As an improvement of the above technical solution, the stacking mechanism 4 includes a first pneumatic slider 41, a first hydraulic telescopic rod 42, a cross rod 43, a clamping plate 44, a pull rod 45, a second hydraulic telescopic rod 46 and a first pneumatic slide rail 47, a first pneumatic slide rail 47 is installed at the top end of each of the regions, and a first pneumatic slider 41 is slidably connected to the bottom end of the first pneumatic slide rail 47; a first hydraulic telescopic rod 42 is installed at the bottom end of the first pneumatic sliding block 41, and a cross rod 43 is fixed at the bottom end of the first hydraulic telescopic rod 42; a second hydraulic telescopic rod 46 is initially fixed in the bottom end of the cross rod 43, and clamping plates 44 are rotatably connected to two sides of the bottom end of the cross rod 43; the center of the clamping plate 44 is rotatably connected with a pull rod 45, and the top end of the pull rod 45 is rotatably connected with the bottom end of the second hydraulic telescopic rod 46.

Fig. 1 is a schematic diagram showing the overall structure of the new embodiment of the present invention, exemplarily, as shown in fig. 1, including a base 2, a feeding conveyor belt 21 is provided on the top end of the base 2, and a scanning box 9 is provided on the top end of the feeding conveyor belt 21; an RFID label reader-writer is arranged inside the scanning box 9, and the scanning box 9 is electrically connected with the industrial personal computer 7; the end part of the feeding conveyer belt 21 is provided with a lifting mechanism 8, and the side part of the lifting mechanism 8 is provided with a steering mechanism 5; the side part of the lifting mechanism 8 is provided with a transfer conveyer belt 3, the side part of the transfer conveyer belt 3 is communicated with a container 1, and the container 1 is provided with two or more than two parts, so that different types of parts can be placed conveniently; the interior of the container 1 is partitioned into a plurality of areas by supporting plates 11, and the top end of each area is provided with a stacking mechanism 4.

The structure of the lifting mechanism 8 is as shown in fig. 2, and includes a first lifting member 81 and a second lifting member 82 which are symmetrically arranged and have the same structure, and the first lifting member 81 includes a first roller 811, a tray 812, a sprocket 813, a bracket 814, a second roller 815 and a motor 816, the first roller 811 and the second roller 815 are connected by the sprocket 813, and the tray 812 is distributed on the surface of the sprocket 813; the first roller 811 and the second roller 815 are fixed by a bracket 814, and the second roller 815 is connected to a motor 816. The cross section of the tray 812 adopts an L-shaped structure, and the trays 812 are distributed at equal intervals.

As shown in fig. 3, the stacking mechanism 4 includes a first pneumatic slider 41, a first hydraulic telescopic rod 42, a cross rod 43, a clamping plate 44, a pull rod 45, a second hydraulic telescopic rod 46 and a first pneumatic slide rail 47, a first pneumatic slide rail 47 is installed at the top end of each of the regions, and the first pneumatic slider 41 is slidably connected to the bottom end of the first pneumatic slide rail 47; a first hydraulic telescopic rod 42 is installed at the bottom end of the first pneumatic sliding block 41, and a cross rod 43 is fixed at the bottom end of the first hydraulic telescopic rod 42; a second hydraulic telescopic rod 46 is initially fixed in the bottom end of the cross rod 43, and clamping plates 44 are rotatably connected to two sides of the bottom end of the cross rod 43; the center of the clamping plate 44 is rotatably connected with a pull rod 45, and the top end of the pull rod 45 is rotatably connected with the bottom end of the second hydraulic telescopic rod 46.

As shown in fig. 4, the steering mechanism 5 includes a baffle 51, a second pneumatic slide block 52, a second pneumatic slide rail 53, a third hydraulic telescopic rod 54 and a push plate 55, the second pneumatic slide rail 53 is mounted at a side portion of a bracket 814, and the side portion of the second pneumatic slide rail 53 is slidably connected to the second pneumatic slide block 52; a baffle plate 51 is fixed on the side part of the second pneumatic slide block 52, and a third hydraulic telescopic rod 54 is fixed on the side part of the baffle plate 51; a push plate 55 is fixed on the side of the third hydraulic telescopic rod 54.

5-7 show a schematic view of the parts box 6, and illustratively, as shown in FIGS. 5-7, the parts box 6 is provided with an RFID tag 61 on a surface thereof and one or more partitions 62 inside the parts box 6; fig. 6 shows a schematic structural view of two partition plates 62, for example, the parts box 6 is divided into four equal division areas by the two partition plates 62; fig. 7 shows a schematic structural view of six partition plates 62, by way of example, the parts box 6 is divided into sixteen equal-divided regions by the six partition plates 62; separate storage of parts of different sizes is performed through the divided areas.

Sticking paper labels 12 to the bottom ends of supporting plates 11 in the container 1, and recording the positions of all places of the container 1 by using the paper labels 12; when goods are stored, parts are stored in a proper part box 6 according to the size, then the part box 6 with the stored parts is placed on a feeding conveyer belt 21, the feeding conveyer belt 21 is opened to convey the part box 6 through the feeding conveyer belt 21, an RFID label 61 on the part box 6 is scanned through a scanning box 9, and a container 1 needing to be stored and the position in the container 1, namely the position marked by the paper label 12, are determined on an industrial personal computer 7 according to the types of the parts; when the parts box 6 is conveyed into the lifting mechanism 8, the parts box 6 is lifted by the lifting mechanism 8; the lifting mechanism 8 has the working principle that the motor 816 is started, the motor 816 drives the roller to rotate when working, the roller is meshed with the chain wheel 813, the chain wheel 813 is further driven to rotate to drive the tray 812 to lift, and the part box 6 can be further driven to move to the preset height; then, pushing the goods into the surface of the transfer conveyor belt 3 through the steering mechanism 5, wherein the steering mechanism 5 has the working principle that the goods are moved to the position of the part box on the second pneumatic slide rail 53 through the second pneumatic slide block 52, then starting the third hydraulic telescopic rod 54, and driving the push plate 55 to push the part box 6 to enter the surface of the transfer conveyor belt 3 by using the third hydraulic telescopic rod 54; then, the stacking mechanism 4 is used for driving the part box 6 to reach the preset position marked by the container 1 and the paper label 12; the stacking mechanism 4 has the working principle that the first hydraulic telescopic rod 42 drives the clamping plates 44 to descend, so that the clamping plates 44 are positioned at two sides of the part box 6, then the second hydraulic telescopic rod 46 is driven to clamp the part box 6, and the part box 6 is driven to move to the position marked by the paper label 11 through the second pneumatic slide block 52 on the second pneumatic slide rail 53, so that the part box 6 is driven to move to the position marked by the paper label 11 to store the part box 6; when goods are delivered from a warehouse, the position of a part box 6 needing to be delivered is determined through an industrial personal computer 7 (such as an industrial personal computer for example), the goods are moved to the transfer conveying belt 3 through the stacking mechanism 4, the goods are driven to move to the lifting mechanism 8 through the transfer conveying belt 3, the part box 6 can be driven to fall down through reverse work of a motor 816 of the lifting mechanism 8, and the principle of delivering the goods to the warehouse is shown in fig. 8. According to the utility model, the information of the parts is recorded through the RFID tag 61, then the position of the part box 6 for storing the parts is determined through the industrial personal computer 7, the part box 6 is stored at the position, the position is usually marked by the paper tag 12, the parts, the part box 6 and the position in the container 1 can be checked on the industrial personal computer 7, and the management is convenient.

The warehousing equipment manually puts parts into the part boxes, and then controls a mechanical structure through industrial software to put the part boxes into the container for storage, so that warehousing work is realized; when goods are taken, the part box can be sent to a goods taking station under the control of industrial control software; according to the part box, different storage spaces are designed according to the sizes of parts, the space utilization rate of the part box is improved, multiple groups of containers are adopted according to the types of the parts, the container management is more standard, the parts can be delivered into and taken out of the warehouse by operating an industrial computer, the labor intensity is reduced, and the working efficiency is improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (7)

1. An electronic device intelligent warehousing equipment, characterized in that: the system comprises a part box (6), a conveying part and an inventory part, wherein RFID tags (61) are attached to the periphery of the part box (6);

the conveying part comprises a base (2), and a feeding conveying belt (21) is arranged at the top end of the base (2); a scanning box (9) is arranged on the side part of the feeding conveying belt (21), and an RFID label reader-writer is arranged in the scanning box (9); the RFID label reader-writer is used for reading the information of the RFID label (61); the end part of the feeding conveyer belt (21) is connected with a lifting mechanism (8), and the lifting mechanism (8) is connected with a steering mechanism (5);

the inventory part comprises a transfer conveyer belt (3), and one end of the transfer conveyer belt (3) is connected with a lifting mechanism (8); the other end of the transfer conveyor belt (3) is connected with a stacking mechanism (4), and the stacking mechanism (4) is arranged in the container (1); the stacking mechanism (4) is used for storing the part boxes (6) in the container (1), and the container (1) is separated by a supporting plate (11); a plurality of paper labels (12) are attached to the surface of the supporting plate (11).

2. The electronic device intelligent warehousing equipment of claim 1, wherein: one or more partition plates (62) are arranged inside the part box (6), and the part box (6) is equally divided into a plurality of cavities by the partition plates (62).

3. The electronic device intelligent warehousing equipment of claim 1, wherein: the lifting mechanism (8) comprises a first lifting part (81) and a second lifting part (82) which are symmetrically arranged and have the same structure, the first lifting part (81) comprises a first roller (811), a tray (812), a chain wheel (813), a support (814), a second roller (815) and a motor (816), the first roller (811) and the second roller (815) are connected through the chain wheel (813), and the tray (812) is distributed on the surface of the chain wheel (813); the first roller (811) and the second roller (815) are fixed through a bracket (814), and the second roller (815) is connected with a motor (816).

4. The electronic device intelligent warehousing equipment of claim 3, wherein: the cross section of tray (812) adopts "L" font structure, just equidistance distributes between tray (812).

5. The electronic device intelligent warehousing equipment of claim 3, wherein: the steering mechanism (5) comprises a baffle (51), a second pneumatic sliding block (52), a second pneumatic sliding rail (53), a third hydraulic telescopic rod (54) and a push plate (55), the second pneumatic sliding rail (53) is installed on the side portion of the support (814), and the side portion of the second pneumatic sliding rail (53) is connected with the second pneumatic sliding block (52) in a sliding mode; a baffle plate (51) is fixed on the side part of the second pneumatic sliding block (52), and a third hydraulic telescopic rod (54) is fixed on the side part of the baffle plate (51); and a push plate (55) is fixed on the side part of the third hydraulic telescopic rod (54).

6. The electronic device intelligent warehousing equipment of claim 1, wherein: at least two containers (1) are arranged, and the containers (1) are communicated through a stacking mechanism (4); the containers (1) are equally divided into a plurality of areas by supporting plates (11).

7. The electronic device intelligent warehousing equipment of claim 6, wherein: the stacking mechanism (4) comprises a first pneumatic sliding block (41), a first hydraulic telescopic rod (42), a cross rod (43), a clamping plate (44), a pull rod (45), a second hydraulic telescopic rod (46) and a first pneumatic sliding rail (47), the top end of each area is provided with the first pneumatic sliding rail (47), and the bottom end of each first pneumatic sliding rail (47) is connected with the first pneumatic sliding block (41) in a sliding manner; a first hydraulic telescopic rod (42) is installed at the bottom end of the first pneumatic sliding block (41), and a cross rod (43) is fixed at the bottom end of the first hydraulic telescopic rod (42); a second hydraulic telescopic rod (46) is initially fixed in the bottom end of the cross rod (43), and clamping plates (44) are rotatably connected to two sides of the bottom end of the cross rod (43); the center of the clamping plate (44) is rotatably connected with a pull rod (45), and the top end of the pull rod (45) is rotatably connected with the bottom end of the second hydraulic telescopic rod (46).

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