CN220617081U

CN220617081U - Warehouse system of intelligent production line of aluminum alloy profiles

Info

Publication number: CN220617081U
Application number: CN202322343081.2U
Authority: CN
Inventors: 高振华
Original assignee: Jinan Cgma Cnc Machinery Co ltd
Current assignee: Jinan Cgma Cnc Machinery Co ltd
Priority date: 2023-08-30
Filing date: 2023-08-30
Publication date: 2024-03-19
Anticipated expiration: 2033-08-30

Abstract

The utility model discloses a warehousing system of an intelligent production line for aluminum alloy profiles, which comprises a feeding transmission device, a discharging transmission device, a grabbing and storing device and a storage rack; the feeding transmission device is used for feeding and transmitting, the discharging transmission device is used for discharging and transmitting, the feeding transmission device and the discharging transmission device are arranged in parallel, the grabbing storage device is used for feeding and discharging of the storage rack, the grabbing storage device is arranged in the middle of the feeding transmission device and the discharging transmission device in parallel, the storage rack is used for storing processed aluminum alloy profiles, and the storage rack is arranged in the outer sides of the feeding transmission device and the discharging transmission device in parallel. Furthermore, the feeding transmission device, the discharging transmission device, the grabbing storage device and the storage rack are sequentially arranged in parallel to form a module unit, and the processing yield of an aluminum alloy door and window processing enterprise can be increased longitudinally and transversely according to the module unit.

Description

Warehouse system of intelligent production line of aluminum alloy profiles

Technical Field

The utility model discloses a warehousing system of an intelligent production line for aluminum alloy profiles.

Background

Along with the development of industrial technology, aluminum alloy door and window processing enterprises are developing towards intensive and standardized directions, along with the continuous development of the aluminum alloy door and window processing enterprises, more and more large and medium-sized aluminum alloy door and window processing enterprises need stable, reliable and intelligent aluminum alloy section production lines suitable for the aluminum alloy door and window processing industry, the existing intelligent aluminum alloy section production lines are manually transmitted from a machining station to a corner forming station, the production efficiency is low, the labor cost is high, and the requirements of the aluminum alloy door and window processing enterprises cannot be met; even some intelligent assembly line warehousing systems, for example, patent CN202211635131.8A discloses an automatic sorting, storing and feeding method for door and window profiles, which comprises a bin device, a feeding device and a material taking device, wherein the bin device comprises a bin frame and a plurality of storage and conveying mechanisms, and the storage and conveying mechanisms are arranged in the bin frame at intervals up and down; the feeding device comprises a feeding frame and a feeding mechanism, wherein the feeding mechanism can move up and down along the feeding frame, when the feeding mechanism moves to a position with the same height as one of the storage conveying mechanisms along the feeding frame, the movable gear assembly can be meshed with the first transmission assembly, and the feeding driving assembly can drive the storage conveying belt to rotate through the movable gear assembly and the first transmission assembly; the device's feed bin device design is more complicated, and every layer of feed bin frame all sets up a storage conveying mechanism, and the cost is higher.

Disclosure of Invention

The utility model provides a storage method of an intelligent production line of aluminum alloy profiles, which aims to solve the technical problem of automatic transmission from a machining station to a corner combining station in the existing intelligent production line of aluminum alloy profiles.

In order to achieve the above object, the present utility model is realized by the following technical scheme:

a warehousing system of an intelligent production line for aluminum alloy profiles comprises a feeding transmission device, a discharging transmission device, a grabbing and storing device and a storage rack;

the feeding conveying device and the discharging conveying device are arranged in parallel; the feeding transmission device is used for feeding transmission, and the discharging transmission device is used for discharging transmission;

the storage rack is arranged at the outer sides of the feeding transmission device and the discharging transmission device in parallel and is used for storing the processed aluminum alloy section;

the grabbing and storing device is arranged between the feeding transmission device and the discharging transmission device in parallel and used for placing the section bar of the feeding transmission device on the material storage rack and placing the section bar on the material storage rack on the discharging transmission device.

As a further technical scheme, the feeding transmission device, the discharging transmission device, the grabbing storage device and the storage rack are sequentially arranged in parallel to form a module unit, and the processing yield of an aluminum alloy door and window processing enterprise can be increased longitudinally and transversely according to the module unit.

As a further technical scheme, the feeding and conveying device comprises a feeding and conveying table frame, a first driving mechanism, a first profile in-place photoelectric switch and a profile positioning plate, wherein a conveying roller support is arranged on the feeding and conveying table frame, conveying rollers are uniformly arranged on the conveying roller support in parallel, the first driving mechanism drives the conveying rollers to drive, and the first profile in-place photoelectric switch and the profile positioning plate are arranged at the tail end of the conveying table frame.

As a further technical scheme, the section bar locating plate is fixed on a first linear sliding rail unit, the first linear sliding rail unit is fixed on a locating plate fixing plate, and the locating plate fixing plate is fixed at the tail end of the transmission table frame.

As a further technical scheme, ejection of compact transmission device include ejection of compact transmission platform frame, actuating mechanism II and section bar photoelectric switch second in place, be provided with the transmission roller support in the ejection of compact transmission platform frame, parallel evenly arranged has the transmission roller on the transmission roller support, the actuating mechanism II passes through the belt and drives the transmission roller transmission, section bar photoelectric switch second in place sets up the head end at the transmission platform frame.

As a further technical scheme, the grabbing and storing device comprises a vertical frame; an up-down driving mechanism is arranged on the vertical frame; the up-and-down driving mechanism (corresponding to the driving mechanism III and the driving mechanism IV at the back) drives the grabbing and storing cross beam to move up and down in a reciprocating manner; the grabbing and storing cross beam is provided with grabbing and storing manipulators, and the grabbing and storing manipulators can move bidirectionally along the direction perpendicular to the transmission direction of the profile.

As a further technical scheme, the grabbing and storing manipulator is an upper-lower double-layer mechanism, and the movement directions of the upper-lower double-layer mechanism are the same; the first layer of movement is realized by moving the vertical plate and the roller track plate through a gear rack, and the second layer of movement is realized by moving the profile fixing plate and the roller track plate through a gear rack movement linkage synchronous belt.

As a further technical scheme, the material storage rack comprises a main body frame structure and a plurality of rows of material supporting devices fixed on the main body frame.

As a further technical scheme, the main body frame structure comprises a first storage rack arranged at one side of the feeding transmission device and a second storage rack arranged at one side of the discharging transmission device; further, the two side storage frames are connected with the grabbing and storing device through the top cross beam.

The beneficial effects of the embodiment of the utility model are as follows:

according to the utility model, through the mutual matching among the feeding transmission device, the discharging transmission device, the grabbing storage device and the storage rack, the feeding transmission device and the discharging transmission device are reasonably arranged, and specifically, the feeding transmission device and the discharging transmission device are arranged in parallel; the storage rack is arranged on the outer sides of the feeding transmission device and the discharging transmission device in parallel, the grabbing storage devices are arranged between the feeding transmission device and the discharging transmission device in parallel and used for placing the section bars of the feeding transmission device on the storage rack and placing the section bars on the storage rack on the discharging transmission device, the grabbing storage devices can only set one set to store the feeding and grab the discharging materials without a plurality of grabbing storage devices, the cost is successfully reduced, the whole storage system is compact in structure, and compared with the prior art, the large-batch storage of the section bars can be realized, and the occupied area is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it will be apparent that the drawings in the following description are only some embodiments of the present utility model

FIG. 1 is an isometric view of the utility model;

FIG. 2 is an isometric view of a feed conveyor in the utility model;

FIG. 3 is an isometric view of an outfeed conveyor of the utility model;

FIGS. 4 (a) and 4 (b) are perspective views of the gripping and storing device according to the present utility model;

FIG. 5 (a) is a perspective view of a fourth or fifth drive mechanism of the present utility model;

fig. 5 (b) is a left side view of the fourth or fifth drive mechanism of the present utility model;

fig. 6 is an isometric view of a magazine in the present utility model.

The reference numbers shown in the drawings: 1-a feed transfer device; 11-a feed transfer roll; 12-section bar in-place photoelectric switch I; 13-a feed positioning device; 2-a discharge transmission device; 21-a discharge conveyor roll; 22-a section bar in-place photoelectric switch II; 3-grabbing and storing devices; 31-column one; 32-a second upright post; 33-grabbing and storing the cross beam; 34-a third driving mechanism; 35-a driving mechanism IV; 36-a driving mechanism V; 361-a drive mechanism mounting plate; 362-riser; 363-roller track plate; 364-rack; 365-multi-stage gear transmission; 366-section bar mounting plate; 367-synchronous belt; 368—synchronous belt clamping device one; 369-a synchronous belt clamping buffer device; 370 roller one; 371 roller two; 37-a driving mechanism six; 4-a storage rack; 41-a magazine frame body; 42-material supporting device.

Detailed Description

It should be noted that the following detailed description is illustrative and is intended to provide further explanation of the utility model. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present utility model. As used herein, the singular forms also are intended to include the plural forms unless the present utility model clearly dictates otherwise, and furthermore, it should be understood that when the terms "comprise" and/or "include" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof;

for convenience of description, the words "upper", "lower", "left" and "right" in the present utility model, if they mean only the directions of upper, lower, left and right in correspondence with the drawings themselves, are not limiting in structure, but merely serve to facilitate description of the present utility model and simplify description, rather than to indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

The terms "mounted," "connected," "secured," and the like are to be construed broadly and refer to either a fixed connection, a removable connection, or an integral body, for example; the terms are used herein as specific meanings as understood by those of ordinary skill in the art, and are not limited to the following terms.

As introduced by the background technology, the utility model provides a warehousing system of an intelligent production line for aluminum alloy profiles, which aims to solve the technical problems.

In a typical embodiment of the present utility model, as shown in fig. 1, fig. 1 to 6 schematically show a warehousing system of an intelligent production line for aluminum alloy profiles according to an embodiment of the present utility model.

The embodiment discloses a storage method of an intelligent production line of aluminum alloy profiles, which comprises a feeding transmission device 1, a discharging transmission device 2, a grabbing and storing device 3 and a storage rack 4; the feeding conveying device 1 is used for feeding and conveying, the discharging conveying device 2 is used for discharging and conveying, the feeding conveying device 1 and the discharging conveying device 2 are arranged in parallel, the grabbing and storing device 3 is used for feeding and discharging of a material storage rack, the grabbing and storing device 3 is arranged between the feeding conveying device 1 and the discharging conveying device 2 in parallel, the material storage rack 4 is used for storing processed aluminum alloy sections, and the material storage rack 4 is arranged outside the feeding conveying device 1 and the discharging conveying device 2 in parallel; according to the utility model, through the mutual matching among the feeding transmission device, the discharging transmission device, the grabbing storage device and the storage rack, the feeding transmission device and the discharging transmission device are reasonably arranged, and specifically, the feeding transmission device and the discharging transmission device are arranged in parallel; the material storage rack is arranged on the outer sides of the feeding transmission device and the discharging transmission device in parallel, and the grabbing storage device is arranged between the feeding transmission device and the discharging transmission device in parallel and is used for placing the section bar of the feeding transmission device on the material storage rack and placing the section bar on the material storage rack on the discharging transmission device; the automatic storage of the sectional materials is realized, the manual sorting is reduced, and the working efficiency is improved; the whole warehousing system is compact in structure, realizes mass storage of the profiles, and reduces the occupied area.

Furthermore, the feeding transmission device, the discharging transmission device, the grabbing storage device and the storage rack are sequentially arranged in parallel to form a module unit, and the processing yield of an aluminum alloy door and window processing enterprise can be increased longitudinally and transversely according to the module unit.

Further, as shown in fig. 2, the feeding and conveying device 1 comprises a feeding and conveying table frame, a conveying roller bracket is arranged on the feeding and conveying table frame, feeding and conveying rollers 11 are uniformly arranged on the conveying roller bracket in parallel, and a first driving mechanism drives the conveying rollers 11 to drive through a belt;

further, the feeding and conveying device 1 further comprises a first section in-place photoelectric switch 12, the first section in-place photoelectric switch 12 is arranged on a first section in-place photoelectric switch bracket, and the first section in-place photoelectric switch bracket is arranged at the tail end of the conveying table rack;

further, the feeding transmission device 1 further comprises a feeding positioning mechanism, the feeding positioning mechanism comprises a section positioning plate, the section positioning plate is fixed on a first linear sliding rail unit, the first linear sliding rail unit is fixed on a positioning plate fixing plate, and the positioning plate fixing plate is fixed at the tail end of the transmission table frame.

Further clearly: as shown in fig. 3, the discharging and conveying device 2 comprises a discharging and conveying table frame, a conveying roller support is arranged on the discharging and conveying table frame, discharging and conveying rollers 21 are uniformly arranged on the conveying roller support in parallel, the discharging and conveying device comprises a second driving mechanism, the second driving mechanism drives the conveying rollers to drive through a belt, the discharging and conveying device comprises a second section in-place photoelectric switch 22, the second section in-place photoelectric switch 22 is arranged on the second section in-place photoelectric switch support, and the second section in-place photoelectric switch support is arranged at the head end of the conveying table frame.

Further clearly: the grabbing and storing device can be provided with a plurality of modules, the grabbing and storing device is arranged according to the lengths of the discharging and conveying device, the feeding and conveying device and the material storage frame, and the like, as shown in fig. 4 (a) and 4 (b), the grabbing and storing device is a schematic structural diagram when the grabbing and storing device is two modules, the structures of the left and right modules are identical, the two devices can be used for placing the section bar on the feeding and conveying device 1 on the material storage frame 4, or for placing the section bar on the material storage frame 4 on the discharging and conveying device 2, when the number of the section bar on the right side is increased, only the guide rail is needed to be added on the side surface of the previous column, and the middle column can be used universally; the present embodiment describes a structure of a gripping storage apparatus by taking one of them as an example: the grabbing and storing device comprises a base, wherein one end of the base is vertically provided with a first upright column 31, the inner side of the first upright column 31 is vertically provided with two parallel linear slide rail units II, the linear slide rail units II are provided with grabbing and storing a first beam fixing plate, the first grabbing and storing beam fixing plate is provided with a third driving mechanism, and the first grabbing and storing beam fixing plate is fixedly connected with one end of the grabbing and storing beam 33. The base other end vertically be equipped with stand two 32, stand two 32 inboard is vertical to be equipped with two parallel linear slide rail units three, is equipped with on the linear slide rail unit three and snatchs and deposit the crossbeam fixed plate two, snatchs and deposit and be equipped with actuating mechanism four on the crossbeam fixed plate two, snatch and deposit crossbeam fixed plate two and snatch the other end fixed connection who deposits crossbeam 33.

Further, the first upright column 31 and the second upright column 32 are vertically parallel, the second linear sliding rail unit and the third linear sliding rail unit are vertically parallel, and the third driving mechanism and the fourth driving mechanism simultaneously drive the grabbing and storing cross beam to reciprocate up and down from two ends of the material rack.

Further, as shown in fig. 5 (a) and fig. 5 (b), each grabbing and storing beam is provided with a grabbing and storing manipulator, the grabbing and storing manipulator includes two driving mechanisms five 36 and six 37 that move horizontally back and forth, the driving mechanisms five 36 include a driving mechanism mounting plate 361, two vertical plates 362 are fixed on the driving mechanism mounting plate 361 in parallel, a plurality of first rollers 370 are fixed on the top of the outer sides of the two vertical plates 362, a multi-stage rack and pinion transmission device is fixed in the middle of the two vertical plates, racks are fixed at the bottoms of the roller track plates 363, the roller track plates 363 are connected with the two vertical plates 362 in a sliding manner through the rack and pinion transmission device, and the first rollers 370 on the two vertical plates roll in the middle notch of the roller track plates 363.

The roller track plate on sliding connection have section bar fixed plate 366, section bar fixed plate 366 both sides parallel arrangement has the little riser of fixed gyro wheel, is fixed with gyro wheel two 371 on the little riser, gyro wheel two 371 rolls in the both sides notch of roller track plate 363, section bar fixed plate 366 bottom plate be provided with hold-in band clamp piece, hold-in band clamp piece is used for pressing from both sides tight open hold-in band 367 one end, the actuating mechanism bottom plate on be located both sides of riser and be provided with hold-in band clamp buffer 369 for press from both sides the open hold-in band other end, hold-in band 376 move along the synchronous pulley, synchronous pulley is fixed in between notch and the both sides notch in the middle of the gyro wheel track plate, two synchronous pulleys are the diagonal angle and place (for example one sets up the left corner position at the front side of section bar fixed plate 366, the right corner position of the rear side of section bar fixed plate 366 is set up to another), two hold-in band clamp buffer are the relative placement with two synchronous pulleys.

A plurality of first supporting sections along the transmission direction are fixed on the section fixing plate 366, and a plurality of second supporting sections perpendicular to the first supporting sections are also arranged above the first supporting sections and used for taking and placing materials for processing the sections; (first and second supporting profiles see fig. 4 (a) and 4 (b)).

Further clearly: the driving mechanism IV and the driving mechanism five are consistent in structure, and the driving mechanism IV and the driving mechanism five are driven simultaneously to carry out in the process of taking and discharging materials.

Further clearly: the driving mechanism five and the driving mechanism six respectively comprise double-layer bidirectional movement, so that the telescopic material taking and discharging length is ensured, one layer of movement is realized by moving the vertical plate and the roller track plate through the gear rack, and the other layer of movement is realized by moving the profile fixing plate and the roller track plate through the gear rack movement linkage synchronous belt; the movement direction of the upper layer and the lower layer is the same direction movement, for example, the upper layer and the lower layer move leftwards at the same time or move rightwards at the same time; and the movement direction of the driving mechanism five and the driving mechanism six is perpendicular to the transmission direction of the section bar.

Further clearly: the storage rack 4 comprises a main body frame structure 41 and a plurality of rows of material supporting devices 42 fixed on the main body frame. The main frame structure 41 comprises a material storage rack arranged on one side of feeding transmission and a material storage rack arranged on one side of discharging transmission, wherein the feeding transmission and the discharging transmission are arranged on two sides of the upright post along the transmission direction of the section bar. In order to ensure the stability of the whole frame, the two side storage frames are connected with the grabbing storage device through the top cross beam.

Further clearly: the device comprises a section of feeding transmission device, a section of discharging transmission device, a grabbing storage device and storage frames positioned on two sides of the feeding and discharging transmission device, wherein the storage frames can form a unit module, the unit module can be longitudinally or transversely increased according to the quantity of the customer profile reserves, and if the unit module is longitudinally increased, the longitudinal transmission device is required to be increased on the basis of increasing the unit module. If the unit modules are transversely added, the movable slide rail units are only required to be added on the side surfaces of the upright posts of the previous unit module, and the unit modules are added.

As shown in fig. 1 to 6, before the profile is transferred to the storage rack 4, the upper surface of the profile grabbing storage device 3 needs to be lower than the upper edge of the feeding transfer roller, the first driving mechanism on the feeding transfer device 1 drives the transfer roller 11 to transfer the profile along the X-axis direction, after the first 12 photoelectric switch on the feeding transfer device 1 senses the profile in place, the positioning plate device 13 on the feeding transfer device is lifted to position, one end of the profile is attached to the positioning plate, after the positioning, the profile grabbing storage device 3 simultaneously drives the grabbing storage cross beam 33 to lift to the corresponding position along the upright post through the third driving mechanism 34 and the fourth driving mechanism 35, the fifth driving mechanism 36 and the sixth driving mechanism 37 on the grabbing storage device 3 simultaneously drive the grabbing storage cross beam 33 to lift the profile second moving along the direction perpendicular to the profile transfer direction to place the profile on the material supporting device 42 of the storage rack 4, then the storage cross beam 33 descends under the action of the third driving mechanism 34 and the fourth driving mechanism 35, the fifth driving mechanism 36 and the sixth driving mechanism 37 are attached to the material supporting rod on the material supporting device, and then the grabbing storage cross beam 33 returns to the initial state.

When the material is required to be taken from the material storage rack 4, the grabbing storage device 3 drives the grabbing storage cross beam 33 to move up and down along the upright post to the position below the material to be taken through the driving mechanism III 34 and the driving mechanism IV 35, the driving mechanism V36 and the driving mechanism VI 37 on the grabbing storage device 3 simultaneously drive the supporting section II on the grabbing storage device 3 to move left and right to the position below the material to be taken, then the driving mechanism III 34 and the driving mechanism IV 35 simultaneously drive the grabbing storage cross beam 33 to lift the material to the position where the material leaves the material storage rack supporting device 42 surface, the driving mechanism V36 and the driving mechanism VI 37 simultaneously drive the supporting section II on the grabbing storage device 3 to the position above the material discharging transmission roller, the driving mechanism III 34 and the driving mechanism IV 35 simultaneously drive the grabbing storage cross beam 33 to descend to the position where the upper surface of the supporting section II is lower than the upper edge of the material discharging transmission roller, and the section II 22 on the material discharging transmission device in place is sensed by the material discharging transmission roller 21 under the action of the driving mechanism II.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims

1. The storage system of the intelligent production line of the aluminum alloy profiles is characterized by comprising a feeding transmission device, a discharging transmission device, a grabbing and storing device and a storage rack;

2. The storage system of the intelligent production line for the aluminum alloy sections, as set forth in claim 1, wherein the feeding transmission device, the discharging transmission device, the grabbing storage device and the storage rack are sequentially arranged in parallel to form a module unit, and the processing yield of an aluminum alloy door and window processing enterprise can be increased longitudinally and transversely according to the module unit.

3. The storage system of the intelligent production line of the aluminum alloy profiles according to claim 1, wherein the feeding and conveying device comprises a feeding and conveying table frame, a first driving mechanism, a first profile in-place photoelectric switch and a profile positioning plate, a conveying roller is arranged on the feeding and conveying table frame, the first driving mechanism drives the conveying roller to drive, and the first profile in-place photoelectric switch and the profile positioning plate are arranged at the tail end of the conveying table frame.

4. The intelligent aluminum alloy profile production line storage system according to claim 3, wherein the profile positioning plate is fixed on a first linear sliding rail unit, the first linear sliding rail unit is fixed on a positioning plate fixing plate, and the positioning plate fixing plate is fixed at the tail end of the transmission table frame.

5. The storage system of the intelligent production line of the aluminum alloy sections according to claim 1, wherein the discharging and conveying device comprises a discharging and conveying table frame, a driving mechanism II and a section in-place photoelectric switch II, a conveying roller is arranged on the discharging and conveying table frame, the driving mechanism II drives the conveying roller to drive, and the section in-place photoelectric switch II is arranged at the head end of the discharging and conveying table frame.

6. The storage system of the intelligent production line of the aluminum alloy profiles according to claim 1, wherein the grabbing and storing device comprises a vertical frame; an up-down driving mechanism is arranged on the vertical frame; the up-and-down driving mechanism drives the grabbing and storing cross beam to move up and down in a reciprocating manner; the grabbing and storing cross beam is provided with grabbing and storing manipulators, and the grabbing and storing manipulators can move bidirectionally along the direction perpendicular to the transmission direction of the profile.

7. The storage system of the intelligent production line for aluminum alloy profiles according to claim 6, wherein the grabbing and storing manipulator is an upper-layer mechanism and a lower-layer mechanism, and the movement directions of the upper-layer mechanism and the lower-layer mechanism are the same.

8. The storage system of the intelligent production line of the aluminum alloy sections according to claim 1, wherein the storage rack comprises a main body frame structure and a plurality of rows of material supporting devices fixed on the main body frame.

9. The intelligent aluminum alloy profile production line storage system according to claim 8, wherein the main frame structure comprises a first storage rack arranged on one side of the feeding and conveying device and a second storage rack arranged on one side of the discharging and conveying device.

10. The intelligent aluminum alloy section production line storage system according to claim 9, wherein the first storage rack and the second storage rack are connected with the grabbing and storing device through a top cross beam.