阅读说明：本技术 充气玻璃铝条生产线 (Inflatable glass aluminum strip production line ) 是由 王瑛 彭永忠 于 2021-09-07 设计创作，主要内容包括：本发明提供了一种充气玻璃铝条生产线,解决目前市场存在的问题。一种充气玻璃铝条生产线,包括依次设置的上料机构、插接机构、传输机构、切割机构和折弯机构；折弯机构包括旋转折弯单元、铝条定位组件和铝条压紧组件；旋转折弯单元包括旋转电机、旋转主轴和翻转板,旋转电机输出端连接旋转主轴,翻转板与旋转主轴连接为一体；铝条定位组件包括铝条固定端后定位板和铝条固定端下定位板,铝条固定端后定位板连接在铝条固定端下定位板上；铝条压紧组件包括铝条固定端压紧板、铝条折弯端压紧板和压刀。(The invention provides an inflatable glass aluminum strip production line, which solves the problems in the existing market. An inflatable glass aluminum strip production line comprises a feeding mechanism, an inserting mechanism, a transmission mechanism, a cutting mechanism and a bending mechanism which are sequentially arranged; the bending mechanism comprises a rotary bending unit, an aluminum strip positioning assembly and an aluminum strip pressing assembly; the rotary bending unit comprises a rotary motor, a rotary main shaft and a turnover plate, the output end of the rotary motor is connected with the rotary main shaft, and the turnover plate and the rotary main shaft are connected into a whole; the aluminum strip positioning assembly comprises an aluminum strip fixed end rear positioning plate and an aluminum strip fixed end lower positioning plate, and the aluminum strip fixed end rear positioning plate is connected to the aluminum strip fixed end lower positioning plate; the aluminum strip pressing assembly comprises an aluminum strip fixed end pressing plate, an aluminum strip bending end pressing plate and a pressing cutter.)

1. The utility model provides an aerify glass aluminium strip production line which characterized in that: the automatic bending machine comprises a feeding mechanism, an inserting mechanism, a transmission mechanism, a cutting mechanism and a bending mechanism which are arranged in sequence;

the bending mechanism comprises a rotary bending unit, an aluminum strip positioning assembly and an aluminum strip pressing assembly;

the rotary bending unit comprises a rotary motor (8), a rotary main shaft (1) and a turnover plate (7), the output end of the rotary motor (8) is connected with the rotary main shaft (1), and the turnover plate (7) is connected with the rotary main shaft (1) into a whole;

the aluminum strip positioning assembly comprises an aluminum strip fixed end rear positioning plate (2) and an aluminum strip fixed end lower positioning plate (3), and the aluminum strip fixed end rear positioning plate (2) is connected to the aluminum strip fixed end lower positioning plate (3);

the aluminum strip pressing assembly comprises an aluminum strip fixed end pressing plate (4), an aluminum strip bending end pressing plate (6) and a pressing cutter (5), the pressing cutter (5) is driven by a front-back movement unit and a lifting movement unit to adjust the distance between the pressing cutter and a rotating main shaft (1), and the aluminum strip fixed end pressing plate (4) is connected to an aluminum strip fixed end lower positioning plate (3) to be mutually vertical and parallel to an aluminum strip fixed end rear positioning plate (2).

2. The aerated glass aluminum strip production line of claim 1, wherein: the front and rear movement unit comprises a front and rear driving cylinder (38) and a movement part (39) connected with the front and rear driving cylinder, and the lifting movement unit is a multi-stage cylinder (40) and is arranged perpendicular to the axis of the front and rear driving cylinder.

3. The aerated glass aluminum strip production line of claim 1, wherein: the cutting mechanism comprises a working table plate (33), a cutting unit, a cutting positioning unit, an adjusting unit and a guide plate (10), wherein

The working table plate (33) and the lower positioning plate (3) at the fixed end of the aluminum strip are on the same plane;

the cutting unit comprises a cutting motor (41), a belt transmission pair (42), a cutting main shaft (13) and a saw blade (12), the cutting motor (41) is connected with the cutting main shaft (13) through the belt transmission pair (42), and the cutting main shaft (13) is connected with the saw blade (12);

the adjusting unit comprises a moving cylinder (43), a moving seat and a guide rail sliding block pair (14), the driving end of the moving cylinder (43) is connected with the moving seat, and the guide rail sliding block pair (14) is formed between the moving seat and the workbench plate (33);

the cutting positioning unit comprises a positioning cylinder (45), a cutting rear positioning plate (9) and a cutting pressing plate (11), the cutting rear positioning plate (9) and the aluminum strip fixed end rear positioning plate (2) are on the same plane, and the positioning cylinder (45) drives the cutting pressing plate (11) to be close to or far away from the cutting rear positioning plate (9);

the guide plate (10) is of a bending structure and is connected to the workbench plate (33).

4. The aerated glass aluminum strip production line of claim 1, wherein: the transmission mechanism comprises an upper transmission unit and a lower transmission unit;

the upper transmission unit comprises an upper belt wheel I (50), an upper belt wheel II (46) and an upper transmission belt (18), and a tensioning cylinder (15) is connected in the upper transmission belt (18);

the lower transmission unit comprises a lower belt wheel I (49), a lower belt wheel II (47), a lower transmission belt (17) and a tension wheel (48), and the lower transmission unit further comprises a lower positioning belt supporting plate (16) connected below the upper transmission unit.

5. The aerated glass aluminum strip production line of claim 1, wherein: the splicing mechanism comprises a stub bar rear positioning (20), a stub bar rear positioning (25), a square rail guide rail pair (19), a stock guide groove bottom plate (22), a stock guide groove pressing plate (23), a splicing cylinder (52), a stub bar pressing plate (21) and a stub bar pressing plate (24), the head rear positioning (20) and the tail rear positioning (25) are connected to the same square rail guide rail pair (19), the head pressing plate (21) is driven by a head cylinder (53) to move back and forth, the tail pressing plate (24) is driven by a tail cylinder (51) to move back and forth, the head pressing plate (21) is driven by a material inserting cylinder (52) to be close to or far away from the tail pressing plate (24) in the direction, the axes of the head cylinder (52) and the head cylinder (53) are perpendicular to each other, the axes of the head cylinder (53) and the tail cylinder (51) are parallel to each other, and the guide chute bottom plate (22) and the guide chute pressing plate (23) are arranged on one side close to the tail pressing plate (24).

6. The aerated glass aluminum strip production line of claim 1, wherein: the feeding mechanism is arranged at intervals more than two groups, the feeding mechanism comprises a feeding trough datum plate (26), a material width limiting plate (29), a supporting cylinder (27) and a pressing cylinder (28), the supporting cylinder (27) and the pressing cylinder (28) are connected to the feeding trough datum plate (26), the axes of the supporting cylinder (27) and the pressing cylinder (28) are perpendicular to each other, and the material width limiting plate (29) is parallel to the feeding trough datum plate (26).

7. The aerated glass aluminum strip production line of any one of claims 1 to 6, wherein: the filling molecular sieve mechanism comprises a square guide rail linear motion pair (30), a pushing cylinder (31) and a machine head (32), wherein the pushing cylinder (31) pushes the machine head (32) to move up and down along the square guide rail linear motion pair (30).

8. The aerated glass aluminum strip production line of any one of claims 1 to 6, wherein: the device also comprises a glue sealing mechanism used in the process of filling the molecular sieve, wherein the glue sealing mechanism comprises a glue pushing cylinder (37), a glue cylinder (34) and a protective cover (35), the glue pushing cylinder (37) and the glue cylinder (34) are coaxially arranged, and the protective cover (35) is connected to the glue cylinder (34) through a locking handle (36).

Technical Field

The invention relates to an inflatable glass aluminum strip production line, and belongs to the technical field of glass processing equipment.

Background

Along with the increase of the requirement of the inflatable glass in the market, the processing requirement of people on the aluminum strips is correspondingly improved, and the aluminum strips with pins cannot meet the requirement of the inflatable glass, so that a production line for automatically bending and then filling the molecular sieve is required.

Bending machines and filling machines on the market have the following problems: 1. the bending arch ridge is large, so that the sealing glue and the sealing are influenced; 2. the efficiency is slow; 3. the transmission precision is poor; 4. the aluminum bar reference is difficult to adjust; 5. the multi-station discharging reference is difficult to adjust; 6. the service life of the filling and pressing structure is short; 7. the glue is not protected, and hands are clamped.

Disclosure of Invention

The invention aims to provide an inflatable glass aluminum strip production line, which solves the problems in the existing market.

In order to achieve the purpose, the invention is realized by the following technical scheme:

an inflatable glass aluminum strip production line comprises a feeding mechanism, an inserting mechanism, a transmission mechanism, a cutting mechanism and a bending mechanism which are sequentially arranged;

the bending mechanism comprises a rotary bending unit, an aluminum strip positioning assembly and an aluminum strip pressing assembly;

the rotary bending unit comprises a rotary motor, a rotary main shaft and a turnover plate, the output end of the rotary motor is connected with the rotary main shaft, and the turnover plate and the rotary main shaft are connected into a whole;

the aluminum strip positioning assembly comprises an aluminum strip fixed end rear positioning plate and an aluminum strip fixed end lower positioning plate, and the aluminum strip fixed end rear positioning plate is connected to the aluminum strip fixed end lower positioning plate;

the aluminum strip pressing assembly comprises an aluminum strip fixed end pressing plate, an aluminum strip bending end pressing plate and a pressing cutter, the pressing cutter is driven by a front-back movement unit and a lifting movement unit to adjust the distance between the pressing cutter and a rotating main shaft, and the aluminum strip fixed end pressing plate is connected to the lower aluminum strip fixed end positioning plate to be perpendicular to each other and to be parallel to the rear aluminum strip fixed end positioning plate.

According to the preferable scheme of the production line of the inflatable glass aluminum strips, the front-back movement unit comprises a front-back driving cylinder and a movement part connected with the front-back driving cylinder, and the lifting movement unit is a multi-stage cylinder and is perpendicular to the axis of the front-back driving cylinder.

According to the preferable scheme of the production line of the inflatable glass aluminum strip, the cutting mechanism comprises a working table plate, a cutting unit, a cutting positioning unit, an adjusting unit and a guide plate, wherein the working table plate and the lower positioning plate at the fixed end of the aluminum strip are on the same plane; the cutting unit comprises a cutting motor, a belt transmission pair, a cutting main shaft and a saw blade, wherein the cutting motor is connected with the cutting main shaft through the belt transmission pair, and the cutting main shaft is connected with the saw blade; the adjusting unit comprises a moving cylinder, a moving seat and a guide rail sliding block pair, wherein the driving end of the moving cylinder is connected with the moving seat, and the guide rail sliding block pair is formed between the moving seat and the working table plate; the cutting positioning unit comprises a positioning cylinder, a cutting rear positioning plate and a cutting pressing plate, the cutting rear positioning plate and the aluminum strip fixed end rear positioning plate are on the same plane and are driven by the positioning cylinder, and the cutting pressing plate is close to or far away from the rear positioning plate; the guide plate is of a bending structure and is connected to the working table plate.

According to the preferable scheme of the production line of the inflatable glass aluminum strip, the transmission mechanism comprises an upper transmission unit and a lower transmission unit; the upper transmission unit comprises an upper belt wheel I, an upper belt wheel II and an upper transmission belt, and a tensioning cylinder is connected in the upper transmission belt; the lower transmission unit comprises a lower belt wheel I, a lower belt wheel II, a lower transmission belt and a tensioning wheel, and the lower transmission unit further comprises a lower positioning belt supporting plate connected below the upper transmission unit.

The preferable scheme of the production line of the inflatable glass aluminum strips is that the inserting mechanism comprises a stub bar rear positioning device, a square rail guide rail pair, a guide chute bottom plate, a guide chute pressing plate, an inserting cylinder, a stub bar pressing plate and a stub bar pressing plate, wherein the stub bar rear positioning device and the stub bar rear positioning device are connected to the same square rail guide rail pair, the stub bar pressing plate can move back and forth under the driving of the stub bar cylinder, the inserting cylinder drives the stub bar pressing plate to be close to or far away from the direction of the stub bar pressing plate, the inserting cylinder is perpendicular to the axial line of the stub bar cylinder, the axial lines of the stub bar cylinder and the stub bar cylinder are parallel to each other, and the guide chute bottom plate and the guide chute pressing plate are arranged on one side close to the stub bar pressing plate.

Aerify glass aluminium bar production line preferred scheme, feed mechanism are two sets of above intervals setting, and feed mechanism includes material loading groove datum plate, material width limiting plate, holds up the cylinder and compresses tightly the cylinder and connect on material loading groove datum plate, and holds up the cylinder and compress tightly cylinder axis mutually perpendicular, and material width limiting plate is parallel to each other with material loading groove datum plate.

According to the preferable scheme of the production line of the aerated glass aluminum strip, the production line further comprises a molecular sieve filling mechanism which comprises a square guide rail linear motion pair, a pushing cylinder and a machine head, wherein the pushing cylinder pushes the machine head to move up and down along the square guide rail linear motion pair.

The preferable scheme of the production line of the inflatable glass aluminum strips further comprises a glue sealing mechanism during filling of the molecular sieve, wherein the glue sealing mechanism comprises a glue pushing cylinder, a glue cylinder and a protective cover, the glue pushing cylinder and the glue cylinder are coaxially arranged, and the protective cover is connected to the glue cylinder through a locking handle.

The invention has the advantages that:

1. the bending positioning reference ensures that the bending phenomenon can not occur.

2. The cutting mechanism ensures the cutting precision and improves the efficiency and the finish degree of the end surface.

3. The tensioning cylinder is connected in the upper transmission belt, so that the tensioning reduces the cost and the installation trouble, and the consistency of the gaps on two sides of the belt is ensured.

4. The plug-in connection on the same guide rail ensures the back positioning reference and the installation convenience, and ensures the plug-in connection precision and rigidity.

5. The material loading guarantees the consistency of the material tanks and the working time of the front and the back material tanks on the same datum plane through laser cutting.

6. The molecular sieve compact square rail structure ensures that the rigidity is sufficient after frequent movement, and the precision is unchanged.

7. The glue filling protection device ensures the safety.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a schematic illustration of selected embodiments of the present invention.

FIG. 2 is a schematic view of a bend of selected embodiments of the present invention.

FIG. 3 is a schematic cut-away view of a selected embodiment of the present invention.

Fig. 4 is a schematic illustration of belt transmission according to selected embodiments of the present invention.

FIG. 5 is a schematic illustration of the plugging of selected embodiments of the present invention.

FIG. 6 is a schematic view of a loading process according to selected embodiments of the present invention.

Fig. 7 is a schematic illustration of molecular sieve filling in accordance with selected embodiments of the present invention.

FIG. 8 is a schematic view of the glue shield of selected embodiments of the present invention.

In the figure: 1. rotating a main shaft, 2, positioning the fixed end of an aluminum strip backwards, 3, positioning the lower fixed end of the aluminum strip, 4, pressing a plate at the fixed end of the aluminum strip, 5, pressing a knife, 6, pressing a plate at the bent end of the aluminum strip, 7, a turnover plate, 8, a rotating motor, 9, positioning the plate after cutting, 10, a guide plate, 11, a pressing and cutting plate, 12, a saw blade, 13, a main cutting shaft, 14, a guide rail slider pair, 15, a tensioning cylinder, 16, a lower positioning belt supporting plate, 17, a lower transmission belt, 18, an upper transmission belt, 19, a square rail guide rail pair, 20, positioning the rear end of the material head, 21, a pressing plate at the material head, 22, a bottom plate of a guide chute, 23, a pressing plate of the guide chute, 24, a pressing plate at the tail, 25, positioning the rear end of the material, 26, a reference plate of a feeding chute, 27, a supporting cylinder, 28, a pressing cylinder, 29, a limiting plate at the material width, 30, a linear motion pair of a square rail, 31, a pushing cylinder, 32, a machine head, 33, and a working table plate, 34. the device comprises a rubber cylinder, 35, a protective cover, 36, a locking handle, 37, a rubber pushing cylinder, 38, a front and back driving cylinder, 39, a moving part, 40, a multi-stage cylinder, 41, a cutting motor, 42, a belt transmission pair, 43, a moving cylinder, 44, a moving seat, 45, a positioning cylinder, 46, an upper belt wheel II, 47, a lower belt wheel II, 48, a tensioning wheel, 49, a lower belt wheel I, 50, an upper belt wheel I, 51, a material tail cylinder, 52, a material inserting cylinder, 53, a material head cylinder, 54, a feeding mechanism, 56, an inserting mechanism, 57, a transmission mechanism, 58, a cutting mechanism, 59 and a bending mechanism.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "vertical", "upper", "lower", "horizontal", and the like indicate directions

The positional or positional relationship is based on that shown in the drawings and is for convenience of description and simplicity of illustration only

Rather than indicating or implying that the device or element so referred to must have a particular orientation, be constructed and arranged in a particular orientation

Operation, and therefore, should not be construed as limiting the invention.

Referring to fig. 1, the production line of the air-filled glass aluminum strips comprises a feeding mechanism 54, an inserting mechanism 56, a transmission mechanism 57, a cutting mechanism 58 and a bending mechanism 59 which are arranged in sequence, and is matched with a molecular sieve filling machine to form a production line.

Referring to fig. 2, the bending mechanism includes a rotary bending unit, an aluminum strip positioning assembly, and an aluminum strip pressing assembly; the rotary bending unit comprises a rotary motor 8, a rotary main shaft 1 and a turnover plate 7, the output end of the rotary motor 8 is connected with the rotary main shaft 1, and the turnover plate 7 is connected with the rotary main shaft 1 into a whole; the aluminum strip positioning assembly comprises an aluminum strip fixed end rear positioning plate 2 and an aluminum strip fixed end lower positioning plate 3, and the aluminum strip fixed end rear positioning plate 2 is connected to the aluminum strip fixed end lower positioning plate 3; the aluminum strip pressing assembly comprises an aluminum strip fixed end pressing plate 4, an aluminum strip bending end pressing plate 6 and a pressing cutter 5, the pressing cutter 5 is driven by a front-back movement unit and a lifting movement unit to adjust the distance between the pressing cutter and a rotating main shaft 1, and the aluminum strip fixed end pressing plate 4 is connected to an aluminum strip fixed end lower positioning plate 3 to be mutually vertical and parallel to an aluminum strip fixed end rear positioning plate 2.

In this embodiment, the forward/backward movement unit includes a forward/backward driving cylinder 38 and a moving member 39 connected to the forward/backward driving cylinder, and the lifting/lowering movement unit is a multi-stage cylinder 40 and is disposed perpendicular to the axis of the forward/backward driving cylinder.

In this embodiment, 3 for the square guide rail pairs of locating plate are fixed down as down location under the aluminium strip stiff end, aluminium strip stiff end pressure strip 4 is fixed mutually perpendicularly and is parallel with aluminium strip stiff end back-locating plate 2 on aluminium strip stiff end locating plate 3, aluminium strip bending end pressure strip 6 and aluminium strip stiff end pressure strip 4 are on the coplanar and aluminium strip bending end pressure strip 6 can rotate, aluminium strip bending end pressure strip 6 card is on returning face plate 7, along returning face plate 7 along with aluminium strip bending end pressure strip 6 seesaw and can be along with the main shaft 1 synchronous revolution of bending.

When the aluminum strip is positioned on the rotating main shaft 1 and the aluminum strip fixed end rear positioning plate 2, the aluminum strip is positioned on the aluminum strip fixed end lower positioning plate 3, the aluminum strip bending end pressing plate 6 and the aluminum strip fixed end pressing plate 4 compress the aluminum strip, the pressing knife 5 presses the inner angle of the aluminum strip, the rotating motor 8 sends a signal to rotate the rotating main shaft 1, the turnover plate 7 rotates synchronously, the bending is formed, and the phenomenon that the bending part arches the ridge is avoided.

Referring to fig. 3, the cutting mechanism includes a work table plate 33, a cutting unit, a cutting positioning unit, an adjusting unit and a guide plate 10, wherein the work table plate 33 is in the same plane with the lower positioning plate 3 for fixing ends of the aluminum bars; the cutting unit comprises a cutting motor 41, a belt transmission pair 42, a cutting main shaft 13 and a saw blade 12, wherein the cutting motor 41 is connected with the cutting main shaft 13 through the belt transmission pair 42, and the cutting main shaft 13 is connected with the saw blade 12; the adjusting unit comprises a moving cylinder 43, a moving seat and a guide rail sliding block pair 14, wherein the driving end of the moving cylinder 43 is connected with the moving seat 44, and the guide rail sliding block pair 14 is formed between the moving seat 44 and the workbench plate 33; the cutting positioning unit comprises a positioning cylinder 45, a cutting rear positioning plate 9 and a cutting pressing plate 11, the cutting rear positioning plate 9 and the aluminum strip fixed end rear positioning plate 2 are on the same plane and are driven by the positioning cylinder 45, and the cutting pressing plate 11 is close to or far away from the rear positioning plate 9; the guide plate 10 has a bent structure and is connected to the table plate 33.

The working process of the invention is as follows: the aluminum strip is folded to be required in shape and needs to be cut off, the aluminum strip is positioned on the working table plate 33, the working table plate 33 and the lower positioning plate 3 of the fixed end of the aluminum strip are on the same plane, the cutting rear positioning plate 9, the rotating main shaft 1 and the rear positioning plate 2 of the fixed end of the aluminum strip are on the same plane, the aluminum strip passes through the aluminum strip guide plate 10 and is a linear type for ensuring the aluminum strip, the cutting pressing plate 11 presses the aluminum strip tightly, the saw blade 12 is installed on the cutting main shaft 13 and is cut through the motion of the guide rail sliding block pair 14, and the cutting precision and the end surface finish degree of the aluminum strip are ensured.

Referring to fig. 4, the transfer mechanism includes an upper transfer unit and a lower transfer unit; the upper transmission unit comprises an upper belt wheel I50, an upper belt wheel II 46 and an upper transmission belt 18, the upper transmission belt 18 is internally connected with a tensioning cylinder 15, the left tensioning cylinder and the right tensioning cylinder 15 are respectively used for adjusting and tensioning the upper transmission belt 18, so that the aluminum strips are consistent in compression degree, synchronous in numerical control transmission, not skid and not squash, the aluminum strips are simple and easy to adjust, and the problem that the aluminum strips on two sides are complex in structure and difficult to adjust in the market and are consistent in compression is solved; the lower transmission unit comprises a lower belt wheel I49, a lower belt wheel II 47, a lower transmission belt 17 and a tension wheel 48, the lower transmission unit also comprises a lower positioning belt supporting plate 16 connected below the upper transmission unit, the lower positioning belt supporting plate 16 ensures that the positioning surface of the lower transmission belt 17, the lower positioning plate 3 for fixing the aluminum strip and the working table plate 33 are on the same plane,

referring to fig. 5, the plugging mechanism includes a stub bar rear positioning 20, a stub bar rear positioning 25, a square rail guide rail pair 19, a guide chute bottom plate 22, a guide chute pressing plate 23, a plugging cylinder 52, a stub bar pressing plate 21 and a stub bar pressing plate 24, the stub bar rear positioning 20 and the stub bar rear positioning 25 are connected to the same square rail guide rail pair 19, the stub bar pressing plate 21 is driven by a stub bar cylinder 53 to move back and forth, the stub bar pressing plate 24 is driven by a stub bar cylinder 51 to move back and forth, the plugging cylinder 52 drives the stub bar pressing plate 21 to approach or leave the stub bar pressing plate 24, the axes of the plugging cylinder 52 and the stub bar cylinder 53 are perpendicular to each other, the axes of the stub bar cylinder 53 and the stub bar cylinder 51 are parallel to each other, and the guide chute bottom plate 22 and the guide chute pressing plate 23 are arranged on one side close to the stub bar pressing plate 24.

The length continuity of the aluminum strip is realized by adopting the inserting mechanism. In order to ensure that the back reference of the aluminum strip is consistent, the stub bar back positioning 20 and the stub bar back positioning 25 are fixed on the same square rail guide rail pair 19, so that the back positioning is easily realized on the same plane, the stub bar back positioning 20 and the stub bar back positioning 25 are in the same plane with the front cutting back positioning plate 9, and the rotating main shaft 1 and the aluminum strip fixed end back positioning plate 2 are in the same plane. The aluminum strip passes through the guide chute bottom plate 22 and the guide chute pressing plate 23, the only position of the aluminum strip is guaranteed, the tail pressing plate 24 presses the tail of the loaded material, the stub bar pressing plate 21 presses the stub bar of the loaded material, the stub bar pressing plate is positioned on the same plane after the loading, the guide chute structure is added, and the splicing of the front material and the rear material is guaranteed to be correct due to the fact that the front material and the rear material are spliced and move on the same kinematic pair 19.

Referring to fig. 6, the feeding mechanisms are arranged at intervals of more than two groups, each feeding mechanism comprises a feeding trough datum plate 26, a material width limiting plate 29, a supporting cylinder 27 and a pressing cylinder 28, the supporting cylinder 27 and the pressing cylinder 28 are connected to the feeding trough datum plate 26, the axes of the supporting cylinder 27 and the pressing cylinder 28 are perpendicular to each other, and the material width limiting plates 29 are parallel to the feeding trough datum plates 26.

In the embodiment, the two-station material groove is not limited to two, three or four material grooves, and the most essential is the laser cutting upper material groove reference plate 26, which can ensure that the relation between each station is equal distance, that is, the position of one material groove is adjusted, and the materials of other material grooves are naturally pushed to the front by the air cylinder and coincide with the original position. The processing method solves the problems of troublesome adjustment and difficult adjustment. Each kind of aluminum strip has a width, and in order to prevent the aluminum strip from turning over at will, a material width limiting plate 29 is arranged, so that the aluminum strip passes through the supporting cylinder 27 and then compresses the cylinder 28, and the purpose of processing the next aluminum strip can be achieved.

Referring to fig. 7, after the aluminum strip is bent, the molecular sieve filling is performed, and the molecular sieve filling includes a glue filling mechanism and a glue sealing mechanism, including a square guide rail linear motion pair 30, a pushing cylinder 31 and a machine head 32, where the pushing cylinder 31 pushes the machine head 32 to move up and down along the square guide rail linear motion pair 30. The glue sealing mechanism comprises a glue pushing cylinder 37, a glue cylinder 34 and a protective cover 35, the glue pushing cylinder 37 and the glue cylinder 34 are coaxially arranged, and the glue cylinder 34 is connected with the protective cover 35 through a locking handle 36. The invention solves the problem that the molecular sieve head frequently compresses aluminum strips for filling, adopts the square guide rail linear motion pair 30 to drive the cylinder 31 to ventilate, and the head 32 moves up and down along the square guide rail linear motion pair 30, thereby ensuring the rigidity and the service life. The problems that the gap is increased and the movement is unstable after the circular guide rail with the diameter of 12 on the market moves for a period of time are solved. Referring to fig. 8, a piston rod is arranged on the glue pushing cylinder 37, the axis is coaxial with the glue cylinder 34, when glue is needed to be applied, the locking handle 36 is loosened, the lower protective cover 35 is turned over, the glue pushing cylinder 37 is powered off for protection, glue is applied to the glue cylinder 34 at the moment, the protective cover 35 is locked by the locking handle 36 after glue is applied, and the glue pushing cylinder 37 can work, so that the safety is improved.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.