CN219253228U - Continuous aluminum-plastic material separation and recovery equipment - Google Patents

Abstract

The application discloses continuity plastic-aluminum material separation recovery plant relates to material separation technical field, has improved the inconvenient problem of operating personnel use, and it includes organism, feeding pipeline and ejection of compact pipeline, is provided with the feeding belt on the feeding pipeline, is provided with first driving medium on the feeding pipeline, is provided with the ejection of compact belt on the ejection of compact pipeline, is provided with the second driving medium on the ejection of compact pipeline, and one side that the feeding pipeline kept away from the organism still is provided with the feeding seat; the feeding seat is provided with an air ejector pipe, the feeding seat is provided with a first ventilation plate and a second ventilation plate, the first ventilation plate is provided with a first ventilation hole, the second ventilation plate is provided with a second ventilation hole, and when the first ventilation plate is abutted to the second ventilation plate, the first ventilation hole and the second ventilation hole are staggered; be provided with a plurality of fixed subassembly on the feeding seat, still be provided with the rocking subassembly that the control second ventilative board rocked on the feeding seat. The application can be convenient for operators to use.

Description

Continuous aluminum-plastic material separation and recovery equipment

Technical Field

The application relates to the technical field of material separation, in particular to continuous aluminum plastic material separation and recovery equipment.

Background

Packaging materials of various products used in the market are often made of composite materials such as paper and plastic, and when the products are used, the composite materials are difficult to decompose and cause a large amount of pollution to the environment during combustion treatment. Therefore, the device is needed to separate the plastic from the paper, and then the plastic and the paper are recycled or subjected to centralized treatment, so that the environmental protection problem in the urban garbage is solved.

The Chinese patent with publication number of CN211467089U discloses an aluminum-plastic separation device for waste aluminized plastic, which comprises a guard board, a solution box and a fixing frame, wherein a box cover is arranged on the solution box, a wiper plate is further arranged on the solution box, a roller box is arranged in the solution box, a gas collecting hood is arranged between the roller box and the box cover, a hydraulic cylinder is further arranged on the guard board and connected with the fixing frame, and a motor is further arranged on the fixing frame.

Raw materials before carrying out aluminum-plastic separation are mixed and staggered, so that operators need to manually peel off the raw materials which are staggered together before feeding, the operation process is troublesome, in addition, finished products after processing are not connected with next-stage equipment, the operators need to transport the finished products to the next-stage equipment, and the labor capacity of the operators is large when using the equipment, so that the equipment is inconvenient to use.

Disclosure of Invention

In order to facilitate the use of operators, the application provides continuous aluminum plastic material separating and recycling equipment.

The application provides a continuity plastic-aluminum material separation recovery plant adopts following technical scheme:

the continuous aluminum-plastic material separation and recovery device comprises a machine body, a feeding pipeline and a discharging pipeline, wherein a feeding belt is arranged on the feeding pipeline, a first transmission part for controlling the movement of the feeding belt is arranged on the feeding pipeline, a discharging belt is arranged on the discharging pipeline, a second transmission part for controlling the movement of the discharging belt is arranged on the discharging pipeline, and a feeding seat is further arranged on one side, far away from the machine body, of the feeding pipeline;

the feeding seat is provided with an air ejector tube, the feeding seat is provided with a first air-permeable plate and a second air-permeable plate, the first air-permeable plate and the second air-permeable plate are obliquely downwards arranged towards the direction close to a feeding belt, the feeding seat is provided with a feeding groove for the first air-permeable plate and the second air-permeable plate to move, the first air-permeable plate is positioned on one side, far away from the air ejector tube, of the second air-permeable plate, the first air-permeable plate is provided with a first air hole, the second air-permeable plate is provided with a second air hole, and when the first air-permeable plate is abutted to the second air-permeable plate, the first air hole and the second air hole are staggered;

be provided with a plurality of fixed subassembly on the feed seat, when first ventilative board and the ventilative board butt of second are in the same place, fixed subassembly can be in the same place first ventilative board and the ventilative board of second, when first ventilative board and the ventilative board of second separate mutually, fixed subassembly can fix the ventilative board of second on the feed seat, still be provided with the rocking subassembly that the control ventilative board of second rocked on the feed seat.

Through adopting above-mentioned technical scheme, place the raw materials in the feed seat, fix the second ventilative board in the feed seat through fixed subassembly, open the jet-propelled pipe, first ventilative board slides towards keeping away from second ventilative board direction, the air current can blow the raw materials through first bleeder vent and second bleeder vent, the raw materials can be blown away, then close the jet-propelled pipe, fix first ventilative board and second ventilative board together through fixed subassembly, under the effect of rocking the subassembly, raw materials on the first ventilative board are carried in the feed pipe, the feed belt carries the raw materials to the organism in, the part after processing can be transported to next level equipment through the ejection of compact belt in, reduce the step of manual transportation to next level equipment with the finished product, realize the effect that makes things convenient for operating personnel to use.

Optionally, the second ventilative board is located first ventilative board lower extreme department, be provided with a plurality of feed wheel on the feed pipe, still be provided with first rotation piece on the feed pipe, first rotation piece can control one of them feed wheel and rotate, the feeding belt cover is established on the feed wheel, one of them be provided with first rotation axis on the feed wheel, rock the subassembly including rotating the cam and rocking the belt, the one side that first ventilative board was kept away from at the second ventilative board is rotated the cam butt, be provided with the second rotation axis on the rotating the cam, rock the belt cover and establish between first rotation axis and second rotation axis.

Through adopting above-mentioned technical scheme, the feeding belt is moved in the drive of feed wheel, and first rotation axis can drive the rotation of second rotation axis under rocking the cooperation of belt simultaneously, and the rotation cam begins to rotate, and the rotation cam butt is on the ventilative board of second, and ventilative board of second can rock under the action of gravity simultaneously.

Optionally, the mounting groove that supplies first ventilative board card to go into is offered to the second ventilative board, fixed subassembly includes dwang, first plug-in rod and second plug-in rod, offer the first plug-in groove that supplies first plug-in rod male on the feeding seat, the second plug-in groove that supplies second plug-in rod male is offered to the first ventilative board, the dwang rotates to be connected on the second ventilative board, be provided with the butt piece on the dwang, the rotatory in-process of dwang, be equipped with on the butt piece and promote the guide slope that first plug-in rod or second plug-in rod slided towards keeping away from the dwang direction, be provided with the elastic component that control first plug-in rod and second plug-in rod slided towards being close to mutually on the second ventilative board.

Through adopting above-mentioned technical scheme, rotatory dwang, when the butt piece butt on first spliced pole, first spliced pole can insert first grafting inslot this moment, second ventilative board and feed seat fixed connection this moment. When the abutting block abuts against the second inserting connection rod, the second inserting connection rod can be inserted into the second inserting groove, and the second ventilation plate is fixedly connected with the first ventilation plate.

Optionally, the elastic component is the butt extension spring, the one end butt of butt extension spring is on first plug rod, the other end butt of butt extension spring is on the second plug rod.

By adopting the technical scheme, under the action of the tension force of the abutting tension spring, the first inserting connection rod and the second inserting connection rod always slide towards the direction close to each other.

Optionally, part the dwang stretches out on the second ventilative board, dwang week side is provided with the sign piece, sign piece extending direction is parallel to butt piece extending direction each other.

Through adopting above-mentioned technical scheme, can make things convenient for the operator to observe the rotation state of dwang through the sign piece.

Optionally, a rotating gear is disposed on the rotating rod, and the rotating gear is meshed with an adjacent rotating gear.

By adopting the technical scheme, because the rotating gears are meshed with the adjacent rotating gears, all the rotating rods can rotate by controlling one of the rotating gears to rotate.

Optionally, one of the rotating rods is rotatably connected with a clamping block, the second ventilation plate is provided with a first clamping groove and a second clamping groove, and when the abutting block abuts against the first plugging rod, the clamping block can be clamped into the first clamping groove; when the abutting block abuts against the second inserting connection rod, the clamping block can be clamped into the second clamping groove.

By adopting the technical scheme, when the clamping block is inserted into the first clamping groove, the stability of the rotating rod is improved when the fixing component is fixedly connected with the second ventilation plate and the feeding seat; when the clamping block is clamped into the second clamping groove, the possibility of rotation of the rotating rod in the shaking process of the second ventilation plate is reduced.

Optionally, a first guide block is arranged on the side wall of the first ventilation plate, and a first guide groove for sliding of the first guide block is formed in the groove wall of the feed groove; the side wall of the second ventilation plate is provided with a second guide block, and the groove wall of the feeding groove is provided with a second guide groove for the second guide block to slide.

By adopting the technical scheme, the first ventilation plate is kept stable in the sliding process under the cooperation of the first guide block and the first guide groove; under the cooperation of the second guide block and the second guide groove, the second ventilation plate is kept stable in the sliding process.

In summary, the present application includes at least one of the following beneficial effects:

placing the feed chute with the raw materials department, then scattering the raw materials of messy crisscross through the jet pipe, when closing the jet pipe, the raw materials falls on first ventilative board, then starts the feed wheel, rotates the cam and drives second ventilative board and first ventilative board and rock, the raw materials can get into on the feeding belt, carry the organism with the raw materials through the feeding belt in, the part after processing can be through the delivery belt transport to next level equipment in, reduce the step of manual transportation to next level equipment with the finished product, realize the effect that makes things convenient for operating personnel to use.

Drawings

FIG. 1 is a schematic view of the overall structure of the present embodiment;

FIG. 2 is a schematic cross-sectional view of the feed block in this embodiment;

FIG. 3 is a schematic cross-sectional view of the salient shake assembly of the present embodiment;

FIG. 4 is an enlarged schematic view at A in FIG. 2;

fig. 5 is a schematic view of the structure of the rotating lever and the abutting tension spring in the present embodiment.

Reference numerals illustrate: 1. a body; 2. a feed conduit; 21. a feed belt; 22. a feed wheel; 221. a first rotation shaft; 3. a discharge pipe; 31. a discharge belt; 32. a discharging wheel; 4. a feeding seat; 41. a feed chute; 42. a first guide groove; 43. a second guide groove; 44. a first socket groove; 5. a first ventilation plate; 51. a first guide block; 52. a first ventilation hole; 53. a second insertion groove; 6. a second ventilation plate; 61. a second guide block; 62. a second ventilation hole; 63. a mounting groove; 64. a rotating groove; 65. a moving groove; 66. a first clamping groove; 67. a second clamping groove; 7. a gas lance; 8. a fixing assembly; 81. a rotating lever; 811. an abutment block; 8111. a guide slope; 812. identifying the block; 813. rotating the gear; 814. a clamping block; 82. a first plug rod; 83. a second plug rod; 9. an elastic member; 91. abutting against a tension spring; 10. a first rotating member; 101. a first rotating motor; 11. shaking the assembly; 111. rotating the cam; 1111. a second rotation shaft; 112. shaking the belt; 12. a second rotating member; 121. and a second rotating motor.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-5.

The embodiment of the application discloses a continuous aluminum-plastic material separation and recovery device.

Referring to fig. 1, the continuous aluminum plastic material separating and recycling device comprises a machine body 1, a feeding pipeline 2 and a discharging pipeline 3, wherein the feeding pipeline 2 and the discharging pipeline 3 are installed on the machine body 1, the feeding pipeline 2 is obliquely upwards arranged towards the direction close to the machine body 1, the discharging pipeline 3 is obliquely downwards arranged towards the direction close to the machine body 1, and a feeding seat 4 is installed on one side, far away from the machine body 1, of the feeding pipeline 2.

Referring to fig. 2 and 3, a feed chute 41 is formed in the feed seat 4, a first ventilation plate 5 and a second ventilation plate 6 are further mounted on the feed seat 4, the first ventilation plate 5 and the second ventilation plate 6 can move in the feed chute 41, the second ventilation plate 6 and the first ventilation plate 5 are obliquely downwards arranged towards the direction close to the feed pipeline 2, a first guide block 51 is welded on the side wall of the first ventilation plate 5, a first guide groove 42 for enabling the first guide block 51 to slide along the vertical direction is formed in the wall of the feed chute 41, and the first ventilation plate 5 can stably slide in the feed chute 41 under the cooperation of the first guide block 51 and the first guide groove 42. The second guide block 61 is welded on the side wall of the second ventilation plate 6, the second guide groove 43 for sliding the second guide block 61 along the vertical direction is formed on the groove wall of the feed chute 41, and the second ventilation plate 6 can stably slide in the feed chute 41.

Referring to fig. 2 and 3, the first ventilation plate 5 is provided with a plurality of first ventilation holes 52 at the upper end of the second ventilation plate 6, a plurality of second ventilation holes 62 at the second ventilation plate 6, and a mounting groove 63 for mounting the first ventilation plate 5 is provided at the second ventilation plate 6, and when the first ventilation plate 5 enters the mounting groove 63, the first ventilation holes 52 and the second ventilation holes 62 are staggered, and the air lance 7 is mounted at the lower end of the second ventilation plate 6.

Referring to fig. 2 and 4, a plurality of fixing assemblies 8 are installed in the feeding seat 4, the fixing assemblies 8 comprise a rotating rod 81, a first inserting rod 82 and a second inserting rod 83, a rotating groove 64 for the rotating rod 81 to rotate is formed in the second ventilation plate 6, a moving groove 65 for the sliding of the first inserting rod 82 and the second inserting rod 83 is formed in the wall of the rotating groove 64, the first inserting rod 82 and the second inserting rod 83 are located on two sides of the rotating rod 81 respectively, and the sliding direction of the first inserting rod 82 and the second inserting rod 83 is perpendicular to the axial direction of the rotating rod 81.

Referring to fig. 4 and 5, an abutting block 811 is welded to the side wall of the rotating rod 81, the abutting block 811 is also rotatably connected to the rotating groove 64, a guide slope 8111 is provided to the abutting block 811, a first insertion groove 44 into which the first insertion rod 82 is inserted is provided to the groove wall of the feed groove 41, and a second insertion groove 53 into which the second insertion rod 83 is inserted is provided to the first ventilation plate 5.

Referring to fig. 4, when the rotating rod 81 rotates, the first inserting rod 82 abuts against the guide inclined surface 8111, and the first inserting rod 82 slides away from the rotating rod 81 under the action of the guide inclined surface 8111 until the first inserting rod 82 is inserted into the first inserting groove 44, and the second ventilation plate 6 is fixed on the feeding seat 4. The rotating rod 81 continues to rotate, when the second inserting and connecting rod 83 abuts against the guide inclined surface 8111, the second inserting and connecting rod 83 slides in the direction away from the rotating rod 81 under the action of the guide inclined surface 8111 until the second inserting and connecting rod 83 is inserted into the second inserting and connecting groove 53, at this time, the second ventilation plate 6 and the first ventilation plate 5 are fixed together, and at this time, the first ventilation plate 5 abuts against the bottom of the mounting groove 63.

Referring to fig. 4 and 5, an elastic member 9 is further installed in the second ventilation plate 6, the elastic member 9 is an abutment tension spring 91, one end of the abutment tension spring 91 abuts against the first insertion rod 82, and the other end of the abutment tension spring 91 abuts against the second insertion rod 83. When the first inserting and connecting rod 82 is not abutted against the abutting block 811 any more, the first inserting and connecting rod 82 can be separated from the first inserting and connecting groove 44 under the action of the tensile force of the abutting tension spring 91; when the second inserting and connecting rod 83 is not abutted against the abutting block 811 any more, the second inserting and connecting rod 83 can be separated from the second inserting and connecting groove 53 under the action of the tensile force of the abutting tension spring 91.

Referring to fig. 4 and 5, in order to facilitate observation of the rotation state of the rotation lever 81, a part of the rotation lever 81 protrudes from the second ventilation plate 6, and a marking block 812 is welded to the circumferential side of the rotation lever 81, and the extending direction of the marking block 812 is parallel to the extending direction of the abutting block 811. The position of the abutting block 811 can be known by observing the position of the marking block 812, and the slip state of the first and second plug-in rods 82 and 83 can be estimated.

Referring to fig. 3 and 4, a rotation gear 813 is sleeved on the rotation rod 81, the rotation gear 813 is meshed with the adjacent rotation gears 813, and all the rotation rods 81 can rotate by controlling one rotation gear 813 to be convenient for an operator to control.

Referring to fig. 4, a locking block 814 is pivotally connected to one of the rotary rods 81, and a first locking groove 66 and a second locking groove 67 are provided in the second ventilation plate 6: when the abutting block 811 abuts against the first plugging rod 82, the clamping block 814 is rotated, the clamping block 814 can be clamped into the first clamping groove 66, and at this time, the stability of the rotating rod 81 is enhanced when the feeding seat 4 and the second ventilation plate 6 are fixed together by the clamping block 814; when the abutting block 811 abuts against the second insertion rod 83, the abutting block 814 is rotated, the abutting block 814 can be clamped into the second clamping groove 67, and at this time, the stability of the rotating rod 81 is enhanced by the abutting block 814 when the second ventilation plate 6 and the first ventilation plate 5 are fixed together.

Referring to fig. 2 and 3, a feeding belt 21 and a plurality of feeding wheels 22 are installed on a feeding pipe 2, the feeding wheels 22 are rotatably connected in the feeding pipe 2, the feeding belt 21 is sleeved on the feeding wheels 22, a first rotating member 10 is also installed on the feeding pipe 2, the first rotating member 10 is a first rotating motor 101 fixedly installed on the feeding pipe 2, a shaking component 11 is also installed in a feeding seat 4, the rotating component comprises a rotating cam 111 and a shaking belt 112, the rotating cam 111 is rotatably connected in the feeding seat 4 through a shaft, a first rotating shaft 221 is welded on one of the feeding wheels 22, the first rotating shaft 221 and an output shaft of the first rotating motor 101 are welded together, a second rotating shaft 1111 is welded on the rotating cam 111, and the shaking belt 112 is sleeved between the first rotating shaft 221 and the second rotating shaft 1111.

Referring to fig. 2 and 3, the first rotary motor 101 is started, the first rotary shaft 221 starts to rotate, the second rotary shaft 1111 rotates to drive the rotary cam 111 to start to rotate under the cooperation of the shaking belt 112, the rotary cam 111 abuts against the second air-permeable plate 6, and the second air-permeable plate 6 can shake under the action of gravity. Simultaneously, the feeding wheel 22 starts to rotate, and when the raw materials on the first ventilation plate 5 can be rocked to enter the feeding belt 21, the feeding belt 21 can be driven to be far away from the machine body 1.

Referring to fig. 1, a discharge belt 31 and a plurality of discharge wheels 32 are installed on a discharge pipe 3, the discharge wheels 32 are rotatably connected in the discharge pipe 3, the discharge belt 31 is sleeved on the discharge wheels 32, a second rotating member 12 is also installed on the discharge pipe 3, the second rotating member 12 is a second rotating motor 121 fixedly installed on the discharge pipe 3, an output shaft of the second rotating motor 121 is welded on one of the discharge wheels 32, the second rotating motor 121 is started, and one of the discharge wheels 32 starts to rotate, so that the discharge belt 31 is driven to move.

The implementation principle of the continuous aluminum plastic material separation and recovery equipment provided by the embodiment of the application is as follows:

placing the raw materials in the feed chute 41, rotating the rotating gear 813 to enable the clamping block 814 to be abutted to the first inserting connection rod 82, clamping the clamping block 814 into the first clamping groove 66, opening the air injection pipe 7, enabling the first ventilation plate 5 to slide away from the second ventilation plate 6, enabling the air flow to blow the raw materials through the first ventilation holes 52 and the second ventilation holes 62, and enabling the raw materials to be blown away.

Then close the jet-propelled pipe 7, first ventilative board 5 falls into mounting groove 63, the raw materials butt is on first ventilative board 5, then rotatory rotation gear 813 makes joint piece 814 butt on second plug rod 83, and in inserting second joint groove 67 with joint piece 814 card, start first rotation motor 101, rotate cam 111 butt on second ventilative board 6, under the gravity effect of second ventilative board 6, second ventilative board 6 and first ventilative board 5 can give and rock, keep away from on being located first ventilative board 5 can get into feeding belt 21, and carry into organism 1 through feeding belt 21, after organism 1 is to the raw materials processing completion, transport the finished product to next level equipment through ejection of compact belt 31 in, realize the effect that convenient operating personnel used.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. A continuous aluminum plastic material separation recovery plant which characterized in that: the feeding device comprises a machine body (1), a feeding pipeline (2) and a discharging pipeline (3), wherein a feeding belt (21) is arranged on the feeding pipeline (2), a first transmission part for controlling the feeding belt (21) to move is arranged on the feeding pipeline (2), a discharging belt (31) is arranged on the discharging pipeline (3), a second transmission part for controlling the discharging belt (31) to move is arranged on the discharging pipeline (3), and a feeding seat (4) is further arranged on one side, far away from the machine body (1), of the feeding pipeline (2);

the feeding device is characterized in that an air jet pipe (7) is arranged on the feeding seat (4), a first air permeable plate (5) and a second air permeable plate (6) are arranged on the feeding seat (4), the first air permeable plate (5) and the second air permeable plate (6) are obliquely downwards arranged towards the direction close to the feeding belt (21), the feeding seat (4) is provided with a feeding groove (41) for the first air permeable plate (5) and the second air permeable plate (6) to move, the first air permeable plate (5) is positioned on one side, far away from the air jet pipe (7), of the second air permeable plate (6), a first air vent (52) is arranged on the first air permeable plate (5), a second air vent (62) is formed in the second air permeable plate (6), and when the first air permeable plate (5) is abutted to the second air permeable plate (6), the first air vent (52) and the second air vent (62) are staggered;

be provided with a plurality of fixed subassembly (8) on feed seat (4), when first ventilative board (5) and second ventilative board (6) butt together, fixed subassembly (8) can be in the same place first ventilative board (5) and second ventilative board (6), when first ventilative board (5) and second ventilative board (6) phase separation, fixed subassembly (8) can fix second ventilative board (6) on feed seat (4), still be provided with rocking subassembly (11) that control second ventilative board (6) rocked on feed seat (4).

2. The continuous aluminum plastic material separation and recovery device according to claim 1, wherein: the second ventilation board (6) is located first ventilation board (5) lower extreme department, be provided with a plurality of feed wheel (22) on feed pipe (2), still be provided with first rotation piece (10) on feed pipe (2), first rotation piece (10) can control one of them feed wheel (22) rotatory, feed belt (21) cover is established on feed wheel (22), one of them be provided with first rotation axis (221) on feed wheel (22), rock subassembly (11) including rotating cam (111) and rocking belt (112), one side that first ventilation board (5) was kept away from to rotating cam (111) butt is provided with second rotation axis (1111) on second ventilation board (6), rocking belt (112) cover is established between first rotation axis (221) and second rotation axis (1111).

3. The continuous aluminum-plastic material separating and recycling device according to claim 2, wherein: the utility model provides a mounting groove (63) that supplies first ventilative board (5) card to go into has been seted up to second ventilative board (6), fixed subassembly (8) are including dwang (81), first plug-in rod (82) and second plug-in rod (83), offer first plug-in groove (44) that supplies first plug-in rod (82) male on feeding seat (4), second plug-in groove (53) that supplies second plug-in rod (83) male are seted up to first ventilative board (5), dwang (81) rotate and connect on second ventilative board (6), be provided with butt piece (811) on dwang (81), in the rotatory process of dwang (81), be equipped with on butt piece (811) and promote first plug-in rod (82) or second plug-in rod (83) towards the guide slope (8111) that keep away from dwang (81) direction and slide, be provided with on second ventilative board (6) and control first plug-in rod (82) and second plug-in rod (83) towards the elasticity piece (9) that slides towards the looks orientation.

4. A continuous aluminium-plastic material separating and recycling device according to claim 3, characterized in that: the elastic piece (9) is an abutting tension spring (91), one end of the abutting tension spring (91) abuts against the first inserting and connecting rod (82), and the other end of the abutting tension spring (91) abuts against the second inserting and connecting rod (83).

5. The continuous aluminum-plastic material separating and recycling device according to claim 4, wherein: part of the rotating rod (81) extends out of the second ventilation plate (6), a marking block (812) is arranged on the periphery of the rotating rod (81), and the extending direction of the marking block (812) is parallel to the extending direction of the abutting block (811).

6. The continuous aluminum-plastic material separating and recycling device according to claim 5, wherein: the rotating rod (81) is provided with a rotating gear (813), and the rotating gear (813) is meshed with the adjacent rotating gears (813).

7. The continuous aluminum-plastic material separating and recycling device according to claim 6, wherein: one of the rotating rods (81) is rotatably connected with a clamping block (814), the second ventilation plate (6) is provided with a first clamping groove (66) and a second clamping groove (67), and when the abutting block (811) abuts against the first inserting rod (82), the clamping block (814) can be clamped into the first clamping groove (66); when the abutting block (811) abuts against the second insertion rod (83), the clamping block (814) can be clamped into the second clamping groove (67).

8. The continuous aluminum-plastic material separating and recycling device according to claim 7, wherein: the side wall of the first ventilation plate (5) is provided with a first guide block (51), and the wall of the feeding groove (41) is provided with a first guide groove (42) for the first guide block (51) to slide; the side wall of the second ventilation plate (6) is provided with a second guide block (61), and the groove wall of the feed groove (41) is provided with a second guide groove (43) for sliding of the second guide block (61).

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