阅读说明：本技术 一种监控塑料外壳回收处理设备 (Control plastic casing recovery processing equipment ) 是由 符振锋 于 2019-11-13 设计创作，主要内容包括：本发明涉及一种回收处理设备,更具体的说是一种监控塑料外壳回收处理设备,包括轻物质处理机构、开合给料机构、搅碎机构、安全驱动机构,设备能够将轻物质去除,设备能够将轻物质压饼处理,设备能够进行给料,设备能够控制给料的急停,设备能够对塑料进行破碎,所述的轻物质处理机构与搅碎机构相连,搅碎机构与安全驱动机构相连,安全驱动机构与开合给料机构相连。(The invention relates to recycling equipment, in particular to monitoring plastic shell recycling equipment which comprises a light material processing mechanism, an opening and closing feeding mechanism, a stirring mechanism and a safety driving mechanism, wherein the equipment can remove light materials, can press the light materials into cakes to be processed, can feed materials, can control the sudden stop of feeding, can crush plastics, and is connected with the stirring mechanism, the stirring mechanism is connected with the safety driving mechanism, and the safety driving mechanism is connected with the opening and closing feeding mechanism.)

1. The utility model provides a control plastic casing recovery processing equipment, includes light material processing mechanism (1), opens and shuts feed mechanism (2), pulper mechanism (3), safety drive mechanism (4), its characterized in that: the light material processing mechanism (1) is connected with the stirring mechanism (3), the stirring mechanism (3) is connected with the safe driving mechanism (4), and the safe driving mechanism (4) is connected with the opening and closing feeding mechanism (2).

2. The apparatus of claim 1, wherein: the light material treatment mechanism (1) comprises a recovery shell mechanism (1-1), a negative pressure fan mechanism (1-2), a bearing seat (1-3), a cam with a shaft (1-4), a coupler (1-5), an extrusion motor (1-6), an extrusion mechanism (1-7) and a push-pull box mechanism (1-8), wherein the negative pressure fan mechanism (1-2) is arranged in the recovery shell mechanism (1-1), the bearing seat (1-3) is connected with the recovery shell mechanism (1-1), the connection mode of the bearing seat (1-3) and the cam with a shaft (1-4) is bearing connection, the cam with a shaft (1-4) is connected with the extrusion motor (1-6) through the coupler (1-5), and the extrusion motor (1-6) is connected with the bearing seat (1-3), the cam (1-4) with the shaft is in contact fit with the extrusion mechanism (1-7), the extrusion mechanism (1-7) is connected with the recovery shell mechanism (1-1), and the push-pull box mechanism (1-8) is in sliding connection with the recovery shell mechanism (1-1); the recycling shell mechanism (1-1) comprises a bottom plate (1-1-1), a shell body (1-1-2), an upper opening (1-1-3), a lower opening (1-1-4), a sliding shell (1-1-5), a stepped hole (1-1-6) and a partition plate (1-1-7) with an opening, wherein the bottom plate (1-1-1) is connected with the shell body (1-1-2), the shell body (1-1-2) is arranged on the shell body (1-1-2), the lower opening (1-1-4) is arranged on the shell body (1-1-2), the sliding shell (1-1-5) is connected with the shell body (1-1-2), the stepped hole (1-1-6) is arranged on the sliding shell (1-1-5), the sliding shell (1-1-5) is arranged in the shell body (1-1-2); the negative pressure fan mechanism (1-2) comprises an impeller motor (1-2-1) and an impeller (1-2-2), wherein the impeller motor (1-2-1) is connected with the impeller (1-2-2), and the impeller motor (1-2-1) is connected with the shell body (1-1-2); the extrusion mechanism (1-7) comprises a belt rod pressure plate (1-7-1), a spring (1-7-2), a boss (1-7-3), a slide rod (1-7-4), a pulley seat (1-7-5) and a pulley (1-7-6), the belt rod pressure plate (1-7-1) is connected with the boss (1-7-3), the boss (1-7-3) is connected with the slide rod (1-7-4), the slide rod (1-7-4) is connected with the pulley seat (1-7-5), the pulley seat (1-7-5) is connected with the pulley (1-7-6) in a bearing manner, the spring (1-7-2) is sleeved on the belt rod pressure plate (1-7-1), the spring (1-7-2) is abutted against the inner wall of the sliding shell (1-1-5), the pressure plate (1-7-1) with the rod is in sliding connection with the stepped hole (1-1-6), the boss (1-7-3) is in sliding connection with the stepped hole (1-1-6), and the pulley (1-7-6) is in contact fit with the cam (1-4) with the shaft; the push-pull box mechanism (1-8) comprises a handle (1-8-1) and a box body (1-8-2), wherein the handle (1-8-1) is connected with the box body (1-8-2), and the box body (1-8-2) is connected with the shell body (1-1-2) in a sliding manner.

3. The apparatus of claim 1, wherein: the opening and closing feeding mechanism (2) comprises a feeding supporting mechanism (2-1), a feeding hopper mechanism (2-2) and a distributing mechanism (2-3), the feeding supporting mechanism (2-1) is connected with the feeding hopper mechanism (2-2), and the feeding supporting mechanism (2-1) is connected with the distributing mechanism (2-3); the feeding supporting mechanism (2-1) comprises supporting legs (2-1-1), a supporting shell (2-1-2), a step arc-shaped groove (2-1-3), an arc-shaped groove I (2-1-4), a ring plate (2-1-5), a sliding hole (2-1-6) and a feeding hole I (2-1-7), wherein the supporting legs (2-1-1) are connected with the supporting shell (2-1-2), the step arc-shaped groove (2-1-3) is formed in the supporting shell (2-1-2), the arc-shaped groove I (2-1-4) is formed in the supporting shell (2-1-2), the ring plate (2-1-5) is connected with the supporting shell (2-1-2), the sliding hole (2-1-6) is formed in the supporting shell (2-1-2), the feed inlet I (2-1-7) is arranged on the supporting shell (2-1-2); the feeding hopper mechanism (2-2) comprises a belt shaft push fit wheel (2-2-1), a limiting step disc (2-2-2) and a feeding hopper I (2-2-3), the connection mode of the belt shaft push fit wheel (2-2-1) and the feeding hopper I (2-2-3) is that a bearing is connected, and the limiting step disc (2-2-2) is connected with the feeding hopper I (2-2-3); the material distributing mechanism (2-3) comprises an upper wear-resistant block (2-3-1), an upper spring (2-3-2), a rod (2-3-3), a lower spring (2-3-4) and a lower wear-resistant block (2-3-5), the upper wear-resistant block (2-3-1) is connected with the rod (2-3-3), the rod (2-3-3) is connected with the lower wear-resistant block (2-3-5), the upper spring (2-3-2) is sleeved on the rod (2-3-3), the lower spring (2-3-4) is sleeved on the rod (2-3-3), the rod (2-3-3) is connected with a sliding hole (2-1-6) in a sliding manner, the upper spring (2-3-2) is abutted against a supporting shell (2-1-2), the lower spring (2-3-4) is propped against the supporting shell (2-1-2).

4. The apparatus of claim 1, wherein: the stirring mechanism (3) comprises a stirring wheel mechanism (3-1) and a stirring cavity mechanism (3-2), and the stirring wheel mechanism (3-1) is connected with the stirring cavity mechanism (3-2); the stirring wheel mechanism (3-1) comprises a belt shaft stirring wheel (3-1-1), a stirring coupler (3-1-2) and a stirring motor (3-1-3), and the belt shaft stirring wheel (3-1-1) is connected with the stirring motor (3-1-3) through the stirring coupler (3-1-2); the stirring cavity mechanism (3-2) comprises a stirring machine shell (3-2-1), a stirring inlet (3-2-2), a stirring outlet (3-2-3) and a bearing seat A (3-2-4), wherein the stirring inlet (3-2-2) is arranged on the stirring machine shell (3-2-1), the stirring outlet (3-2-3) is arranged on the stirring machine shell (3-2-1), the bearing seat A (3-2-4) is connected with the stirring wheel (3-1-1) with a shaft in a bearing connection mode, the stirring motor (3-1-3) is connected with the stirring machine shell (3-2-1), the pulper shell (3-2-1) is connected with the bottom plate (1-1-1).

5. The apparatus of claim 1, wherein: the safety driving mechanism (4) comprises a pushing cam frame mechanism (4-1), a driving arm mechanism (4-2), a triggering mechanism (4-3), a corner supporting mechanism (4-4), a pulling rod mechanism (4-5), a secondary triggering mechanism (4-6) and a linkage rod mechanism (4-7), the pushing cam frame mechanism (4-1) is hinged with the driving arm mechanism (4-2), the driving arm mechanism (4-2) is connected with the triggering mechanism (4-3), the triggering mechanism (4-3) is in contact fit with the pulling rod mechanism (4-5), the pulling rod mechanism (4-5) is connected with the corner supporting mechanism (4-4), the pulling rod mechanism (4-5) is hinged with the secondary triggering mechanism (4-6), the secondary triggering mechanism (4-6) is connected with the corner supporting mechanism (4-4), the secondary trigger mechanism (4-6) is connected with the linkage rod mechanism (4-7) in a sliding way, and the linkage rod mechanism (4-7) is hinged with the driving arm mechanism (4-2); the pushing cam frame mechanism (4-1) comprises a belt shaft special-shaped wheel (4-1-1), a cam frame body (4-1-2), a belt pulley A (4-1-3), a belt (4-1-4), a belt pulley B (4-1-5), a connecting shaft (4-1-6) and a gear (4-1-7), the connection mode of the belt shaft special-shaped wheel (4-1-1) and the cam frame body (4-1-2) is bearing connection, the belt shaft special-shaped wheel (4-1-1) is connected with the belt pulley A (4-1-3), the belt pulley A (4-1-3) is flexibly connected with the belt (4-1-4), the belt (4-1-4) is flexibly connected with the belt pulley B (4-1-5), the belt pulley B (4-1-5) is connected with the connecting shaft (4-1-6), the connecting shaft (4-1-6) is connected with the cam frame body (4-1-2) in a bearing mode, the connecting shaft (4-1-6) is connected with the gear (4-1-7), and the cam frame body (4-1-2) is connected with the mincing machine shell (3-2-1); the driving arm mechanism (4-2) comprises a driving arm body (4-2-1), a hinged seat A (4-2-2), a feeding motor (4-2-3), a feeding coupler (4-2-4) and a driving gear with a shaft (4-2-5), the driving arm body (4-2-1) is hinged with the cam frame body (4-1-2), the driving arm body (4-2-1) is connected with the hinged seat A (4-2-2), the feeding motor (4-2-3) is connected with the driving arm body (4-2-1), the feeding motor (4-2-3) is connected with the driving gear with the shaft (4-2-5) through the feeding coupler (4-2-4), the driving gear (4-2-5) with the shaft is connected with the driving arm body (4-2-1) by a bearing; the trigger mechanism (4-3) comprises a support I (4-3-1) and a clamping support wheel (4-3-2), the support I (4-3-1) is connected with the clamping support wheel (4-3-2) in a bearing mode, the support I (4-3-1) is connected with the cam frame body (4-1-2), and the clamping support wheel (4-3-2) is in contact fit with the driving arm body (4-2-1); the corner supporting mechanism (4-4) comprises a corner supporting body (4-4-1), a unthreaded hole (4-4-2), a stepped groove (4-4-3), a hole A (4-4-4) and a stepped hole A (4-4-5), wherein the unthreaded hole (4-4-2) is formed on the corner supporting body (4-4-1), the stepped groove (4-4-3) is formed on the corner supporting body (4-4-1), the hole A (4-4-4) is formed on the corner supporting body (4-4-1), the stepped hole A (4-4-5) is formed on the corner supporting body (4-4-1), the stepped groove (4-4-3) is communicated with the hole A (4-4-4), the hole A (4-4-4) is communicated with the stepped hole A (4-4-5), and the corner support body (4-4-1) is connected with the mincing machine shell (3-2-1); the pulling rod mechanism (4-5) comprises a wedge block (4-5-1), a wedge block spring (4-5-2), a pull rod (4-5-3), a hinged groove (4-5-4) and a handle A (4-5-5), the wedge block (4-5-1) is connected with the pull rod (4-5-3), the pull rod (4-5-3) is connected with the handle A (4-5-5), the wedge block spring (4-5-2) is sleeved on the pull rod (4-5-3), the hinged groove (4-5-4) is arranged on the pull rod (4-5-3), and the wedge block spring (4-5-2) is abutted against the corner supporting body (4-4-1); the secondary trigger mechanism (4-6) comprises an inserted link (4-6-1), a rod I (4-6-2) with a boss, a spring A (4-6-3), a connecting seat I (4-6-4) and a hinged connecting rod I (4-6-5), the inserted link (4-6-1) is connected with the rod I (4-6-2) with the boss, the rod I (4-6-2) with the boss is connected with the connecting seat I (4-6-4), the connecting seat I (4-6-4) is hinged with the hinged connecting rod I (4-6-5), the spring A (4-6-3) is sleeved on the rod I (4-6-2) with the boss, the inserted link (4-6-1) is connected with the hole A (4-4-4) in a sliding manner, the rod I (4-6-2) with the boss is connected with the stepped hole A (4-4-5) in a sliding mode, the spring A (4-6-3) is arranged in the stepped hole A (4-4-5), and the hinged connecting rod I (4-6-5) is hinged with the pull rod (4-5-3); the linkage rod mechanism (4-7) comprises a linkage rod body (4-7-1), a linkage stepped sliding seat (4-7-2) and a secondary limiting hole (4-7-3), wherein the linkage rod body (4-7-1) is hinged with the linkage stepped sliding seat (4-7-2), the secondary limiting hole (4-7-3) is formed in the linkage stepped sliding seat (4-7-2), the linkage stepped sliding seat (4-7-2) is in sliding connection with the stepped groove (4-4-3), and the secondary limiting hole (4-7-3) is matched with the inserted rod (4-6-1).

6. A monitored plastic enclosure recycling apparatus as claimed in claim 3, wherein: the material of the feeding hopper I (2-2-3) is high manganese steel.

Technical Field

The invention relates to a recycling device, in particular to a monitoring plastic shell recycling device.

Background

When the waste monitoring equipment is recycled, the recycling of the plastic shell is crucial, most of plastics are not degradable and seriously damage the environment, and the traditional recycling treatment equipment cannot effectively remove light substances and well protect the safety of people, so the recycling treatment equipment for the monitoring plastic shell is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing the monitoring plastic shell recovery processing equipment, the equipment can remove light substances, the equipment can press the light substances into cakes for processing, the equipment can feed the materials, the equipment can control the sudden stop of the feeding, and the equipment can crush the plastic.

In order to solve the technical problem, the invention relates to a recycling device, in particular to a monitoring plastic shell recycling device which comprises a light material processing mechanism, an opening and closing feeding mechanism, a stirring mechanism and a safety driving mechanism, wherein the device can remove light materials, can press light materials into cakes to be processed, can feed materials, can control the feeding to stop suddenly, and can crush plastic.

The light material processing mechanism is connected with the stirring mechanism, the stirring mechanism is connected with the safe driving mechanism, and the safe driving mechanism is connected with the opening and closing feeding mechanism.

As a further optimization of the technical scheme, the light material processing mechanism of the monitoring plastic shell recovery processing equipment comprises a recovery shell mechanism, a negative pressure fan mechanism, a bearing seat, a cam with a shaft, a coupler, an extrusion motor, an extrusion mechanism and a box pushing and pulling mechanism, wherein the negative pressure fan mechanism is arranged in the recovery shell mechanism, the bearing seat is connected with the cam with the shaft in a bearing connection mode, the cam with the shaft is connected with the extrusion motor through the coupler, the extrusion motor is connected with the bearing seat, the cam with the shaft is in contact fit with the extrusion mechanism, the extrusion mechanism is connected with the recovery shell mechanism, and the box pushing and pulling mechanism is in sliding connection with the recovery shell mechanism; the shell recovery mechanism comprises a bottom plate, a shell body, an upper opening, a lower opening, a sliding shell, a stepped hole and a partition plate with an opening, wherein the bottom plate is connected with the shell body; the negative pressure fan mechanism comprises an impeller motor and an impeller, the impeller motor is connected with the impeller, and the impeller motor is connected with the shell body; the extrusion mechanism comprises a belt rod pressure plate, a spring, a boss, a sliding rod, a pulley seat and a pulley, wherein the belt rod pressure plate is connected with the boss, the boss is connected with the sliding rod, the sliding rod is connected with the pulley seat, the pulley seat is connected with the pulley in a bearing mode, the spring is sleeved on the belt rod pressure plate, the spring is abutted against the inner wall of the sliding shell, the belt rod pressure plate is connected with the stepped hole in a sliding mode, the boss is connected with the stepped hole in a sliding mode, and the pulley is in contact fit with the cam with the shaft; the box pushing and pulling mechanism comprises a handle and a box body, the handle is connected with the box body, and the box body is connected with the shell body in a sliding mode.

As a further optimization of the technical scheme, the opening and closing feeding mechanism for monitoring the plastic shell recovery processing equipment comprises a feeding supporting mechanism, a feeding hopper mechanism and a distributing mechanism, wherein the feeding supporting mechanism is connected with the feeding hopper mechanism, and the feeding supporting mechanism is connected with the distributing mechanism; the feeding support mechanism comprises supporting legs, a support shell, a stepped arc-shaped groove, an arc-shaped groove I, a ring plate, a sliding hole and a feeding hole I, wherein the supporting legs are connected with the support shell; the feeding hopper mechanism comprises a belt shaft push fit wheel, a limiting step disc and a feeding hopper I, the belt shaft push fit wheel is connected with the feeding hopper I in a bearing mode, and the limiting step disc is connected with the feeding hopper I; the material distributing mechanism comprises an upper wear-resistant block, an upper spring, a rod, a lower spring and a lower wear-resistant block, wherein the upper wear-resistant block is connected with the rod, the rod is connected with the lower wear-resistant block, the upper spring is sleeved on the rod, the lower spring is sleeved on the rod, the rod is in sliding connection with the sliding hole, the upper spring is abutted against the supporting shell, and the lower spring is abutted against the supporting shell.

As a further optimization of the technical scheme, the stirring mechanism of the monitoring plastic shell recovery processing equipment comprises a stirring wheel mechanism and a stirring cavity mechanism, wherein the stirring wheel mechanism is connected with the stirring cavity mechanism; the stirring wheel mechanism comprises a belt shaft stirring wheel, a stirring coupler and a stirring motor, and the belt shaft stirring wheel is connected with the stirring motor through the stirring coupler; the stirring cavity mechanism comprises a stirring shell, a stirring inlet, a stirring outlet and a bearing seat A, wherein the stirring inlet is formed in the stirring shell, the stirring outlet is formed in the stirring shell, the bearing seat A is connected with a belt shaft stirring wheel through a bearing, a stirring motor is connected with the stirring shell, and the stirring shell is connected with a bottom plate.

As a further optimization of the technical scheme, the safety driving mechanism of the monitoring plastic shell recycling device comprises a pushing cam frame mechanism, a driving arm mechanism, a triggering mechanism, a corner supporting mechanism, a pulling rod mechanism, a secondary triggering mechanism and a linkage rod mechanism, wherein the pushing cam frame mechanism is hinged with the driving arm mechanism, the driving arm mechanism is connected with the triggering mechanism, the triggering mechanism is in contact fit with the pulling rod mechanism, the pulling rod mechanism is connected with the corner supporting mechanism, the pulling rod mechanism is hinged with the secondary triggering mechanism, the secondary triggering mechanism is connected with the corner supporting mechanism, the secondary triggering mechanism is in sliding connection with the linkage rod mechanism, and the linkage rod mechanism is hinged with the driving arm mechanism; the pushing cam frame mechanism comprises a special-shaped wheel with a shaft, a cam frame body, a belt pulley A, a belt pulley B, a connecting shaft and a gear, the special-shaped wheel with the shaft is connected with the cam frame body in a bearing mode, the special-shaped wheel with the shaft is connected with the belt pulley A, the belt pulley A is flexibly connected with the belt, the belt is flexibly connected with the belt pulley B, the belt pulley B is connected with the connecting shaft, the connecting shaft is connected with the cam frame body in a bearing mode, the connecting shaft is connected with the gear, and the cam frame body is connected with the mincing machine; the driving arm mechanism comprises a driving arm body, a hinge seat A, a feeding motor, a feeding coupler and a driving gear with a shaft, wherein the driving arm body is hinged with the cam frame body, the driving arm body is connected with the hinge seat A, the feeding motor is connected with the driving arm body, the feeding motor is connected with the driving gear with the shaft through the feeding coupler, and the driving gear with the shaft is connected with the driving arm body through a bearing; the trigger mechanism comprises a support I and a clamping support wheel, the support I and the clamping support wheel are connected in a bearing mode, the support I is connected with the cam frame body, and the clamping support wheel is in contact fit with the driving arm body; the corner supporting mechanism comprises a corner supporting body, an unthreaded hole, a stepped groove, a hole A and a stepped hole A, wherein the unthreaded hole is formed in the corner supporting body; the pulling rod mechanism comprises a wedge block, a wedge block spring, a pull rod, a hinged groove and a handle A, the wedge block is connected with the pull rod, the pull rod is connected with the handle A, the wedge block spring is sleeved on the pull rod, the hinged groove is formed in the pull rod, and the wedge block spring abuts against the corner support body; the second-stage trigger mechanism comprises an insert rod, a rod I with a boss, a spring A, a connecting seat I and a hinged connecting rod I, wherein the insert rod is connected with the rod I with the boss, the rod I with the boss is connected with the connecting seat I, the connecting seat I is hinged with the hinged connecting rod I, the spring A is sleeved on the rod I with the boss, the insert rod is in sliding connection with a hole A, the rod I with the boss is in sliding connection with a stepped hole A, the spring A is arranged in the stepped hole A, and the hinged connecting rod I is hinged with a pull rod; the linkage rod mechanism comprises a linkage rod body, a linkage stepped sliding seat and a secondary limiting hole, the linkage rod body is hinged with the linkage stepped sliding seat, the secondary limiting hole is formed in the linkage stepped sliding seat, the linkage stepped sliding seat is connected with the stepped groove in a sliding mode, and the secondary limiting hole is matched with the inserted rod.

As a further optimization of the technical scheme, the material of the feeding hopper I of the monitoring plastic shell recycling equipment is high manganese steel.

The monitoring plastic shell recycling equipment has the beneficial effects that:

according to the monitoring plastic shell recycling and processing equipment, light materials can be removed, the equipment can press cakes to process the light materials, the equipment can feed materials, the equipment can control the feeding to stop suddenly, and the equipment can crush plastics.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic sectional structural view of a monitoring plastic casing recycling apparatus according to the present invention.

Fig. 2 is a schematic view of the overall structure of a monitoring plastic casing recycling device of the present invention.

Fig. 3 is a schematic view of a supplementary structure of a monitoring plastic casing recycling apparatus according to the present invention.

Fig. 4 is a schematic structural diagram of a light material processing mechanism 1 for monitoring a plastic casing recycling device according to the present invention.

Fig. 5 is a schematic sectional view showing the structure of a light material processing means 1 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 6 is a schematic structural diagram of a recycling bin mechanism 1-1 for monitoring a recycling facility for plastic shells according to the present invention.

Fig. 7 is a schematic plan view of a recycling bin mechanism 1-1 for monitoring a recycling facility for plastic shells according to the present invention.

Fig. 8 is a schematic structural diagram of a negative pressure fan mechanism 1-2 for monitoring a plastic casing recycling device according to the present invention.

Fig. 9 is a schematic structural view of the extrusion mechanisms 1-7 of the monitoring plastic casing recycling equipment of the invention.

Fig. 10 is a schematic structural view of a box pushing and pulling mechanism 1-8 for monitoring a plastic shell recycling device according to the present invention.

Fig. 11 is a schematic structural diagram of the opening and closing feeding mechanism 2 for monitoring the plastic shell recycling equipment of the invention.

Fig. 12 is a schematic cross-sectional structural view of the opening and closing feeding mechanism 2 for monitoring the plastic shell recycling equipment of the present invention.

Fig. 13 is a schematic structural diagram of a feeding support mechanism 2-1 of a monitoring plastic casing recycling device according to the present invention.

Fig. 14 is a schematic cross-sectional structural view of a feed support mechanism 2-1 for monitoring a plastic shell recycling apparatus according to the present invention.

Fig. 15 is a schematic top view of a feed support mechanism 2-1 for monitoring a plastic casing recycling apparatus according to the present invention.

FIG. 16 is a schematic view showing the structure of a hopper mechanism 2-2 for monitoring a recycling apparatus for plastic shells according to the present invention.

Fig. 17 is a schematic structural diagram of a material distribution mechanism 2-3 for monitoring a plastic shell recycling device according to the present invention.

Fig. 18 is a schematic structural diagram of a mincing mechanism 3 for monitoring a plastic casing recycling device according to the present invention.

Fig. 19 is a schematic sectional structure view of a crushing mechanism 3 for monitoring a plastic casing recycling apparatus according to the present invention.

FIG. 20 is a schematic view showing the construction of a shredder mechanism 3-1 for monitoring a plastic casing recycling apparatus according to the present invention.

FIG. 21 is a schematic structural diagram of a crushing chamber mechanism 3-2 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 22 is a schematic structural diagram of a safety driving mechanism 4 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 23 is a schematic sectional view showing the structure of a safety drive mechanism 4 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 24 is a schematic structural view of a push cam carrier mechanism 4-1 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 25 is a schematic structural view of a driving arm mechanism 4-2 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 26 is a schematic structural view of a trigger mechanism 4-3 for monitoring a plastic casing recycling apparatus according to the present invention.

Fig. 27 is a schematic structural view of a corner support mechanism 4-4 of a monitoring plastic casing recycling apparatus of the present invention.

Fig. 28 is a schematic plan view of a corner support mechanism 4-4 of a monitoring plastic enclosure recycling apparatus of the present invention.

Fig. 29 is a schematic structural diagram of a pulling rod mechanism 4-5 of the monitoring plastic casing recycling device of the invention.

FIG. 30 is a schematic diagram of the structure of a secondary trigger mechanism 4-6 for monitoring the recycling equipment of plastic shells according to the present invention.

FIG. 31 is a schematic structural view of a linkage rod mechanism 4-7 of the monitoring plastic casing recycling device of the present invention.

In the figure: a light material processing means 1; a shell recovery mechanism 1-1; a bottom plate 1-1-1; a housing body 1-1-2; an upper opening 1-1-3; the lower opening is 1-1-4; 1-1-5 of a sliding shell; 1-1-6 of a stepped hole; 1-1-7 of partition board with opening; a negative pressure fan mechanism 1-2; 1-2-1 of an impeller motor; impeller 1-2-2; 1-3 of a bearing seat; 1-4 of cam with shaft; 1-5 of a coupler; 1-6 of an extrusion motor; 1-7 of an extrusion mechanism; a pressure plate with a rod 1-7-1; 1-7-2 of a spring; 1-7-3 of a boss; 1-7-4 slide bars; 1-7-5 pulley seats; 1-7-6 of a pulley; a push-pull box mechanism 1-8; 1-8-1 of a handle; 1-8-2 of a box body; the feeding mechanism 2 is opened and closed; a feeding support mechanism 2-1; 2-1-1 of supporting legs; a support housing 2-1-2; 2-1-3 of a step arc-shaped groove; an arc-shaped groove I2-1-4; 2-1-5 of a ring plate; 2-1-6 of a sliding hole; feed inlet I2-1-7; a hopper mechanism 2-2; the belt shaft pushes the matching wheel 2-2-1; 2-2-2 of a limiting step disc; a feeding hopper I2-2-3; a material distribution mechanism 2-3; 2-3-1 of an upper wear-resistant block; an upper spring 2-3-2; 2-3-3 of the rod; 2-3-4 parts of a lower spring; 2-3-5 parts of lower wear-resistant blocks; a crushing mechanism 3; a mincing wheel mechanism 3-1; a belt shaft crushing wheel 3-1-1; crushing the coupler 3-1-2; 3-1-3 of a mincing motor; a crushing cavity mechanism 3-2; a pulper housing 3-2-1; a crushing inlet 3-2-2; a crushing outlet 3-2-3; bearing seat A3-2-4; a safety drive mechanism 4; pushing the cam carrier mechanism 4-1; 4-1-1 of a special-shaped wheel with a shaft; 4-1-2 parts of a cam frame body; a belt pulley A4-1-3; 4-1-4 of a belt; a belt pulley B4-1-5; connecting shafts 4-1-6; gears 4-1-7; a driving arm mechanism 4-2; a driving arm body 4-2-1; the hinge seat A4-2-2; a feeding motor 4-2-3; 4-2-4 of a feeding coupler; a driving gear 4-2-5 with a shaft; a trigger mechanism 4-3; support I4-3-1; a clamping support wheel 4-3-2; a corner support mechanism 4-4; a corner support body 4-4-1; 4-4-2 of a light hole; 4-4-3 of a stepped groove; aperture A4-4-4; a stepped hole A4-4-5; pulling a rod mechanism 4-5; 4-5-1 of a wedge block; 4-5-2 of a wedge spring; 4-5-3 of a pull rod; 4-5-4 of hinge slotting; handle A4-5-5; 4-6 of a secondary trigger mechanism; 4-6-1 of an inserted link; a rod I4-6-2 with a boss; spring A4-6-3; connecting seat I4-6-4; the hinged connecting rod I4-6-5; 4-7 of a linkage rod mechanism; 4-7-1 of a linkage rod body; 4-7-2 of a linkage step sliding seat; and 4-7-3 secondary limiting holes.

Detailed Description