CN111389997A - Tail stamping device for production of electric automatic refrigerator double-tail filter - Google Patents

Abstract

The invention discloses a tail punching device for producing an electric automatic freezer double-tail filter, which relates to the technical field of freezer production and solves the problems that the existing freezer dry filter can be completed only by punching for many times during punching, the operation is troublesome, the working efficiency is low, and meanwhile, certain danger is caused by manual feeding; the rear end face of the top of the machine body main body is fixedly connected with a group of driving motors; a group of feed driving shafts is rotatably connected to the rear part of the top of the machine body main body; the front end face of the machine body main body is provided with a group of pressing transmission devices and a group of conveying belt devices; and a group of conveyor belt driving shafts are rotatably connected to the rear part of the lower part of the machine body main body. The device has changed and has needed manual material loading many times in the past just can accomplish the problem of punching press, very big simplification the operation, great improvement work efficiency, keep away from the work position in the use, the security is higher.

Description

Tail stamping device for production of electric automatic refrigerator double-tail filter

Technical Field

The invention relates to the technical field of electric automation production, in particular to a tail punching device for production of a double-tail filter of an electric automation freezer.

Background

The freezer dry filter is an essential device of refrigeration equipment such as a freezer, and the freezer dry filter is used for filtering impurities and moisture in a refrigerant in a pipeline of a system, and is generally manufactured by punching through a copper pipe, and is generally punched through a punching machine.

For example, application No.: the invention discloses a punching machine, and belongs to the field of punching equipment. The punching machine comprises a main body frame, wherein the main body frame comprises two vertical plates longitudinally arranged on the front side and the rear side of the main body frame, and the left side and the right side of each vertical plate are respectively connected through corresponding side connecting plates; the bottom end of the side connecting plate is connected with a plurality of bottom reinforcing plates which are parallel to each other. The inner side surface of each side connecting plate is connected with an upper fixing piece and a lower fixing piece, and a guide pillar is arranged between the upper fixing piece and the lower fixing piece; the left side and the right side of the sliding block are respectively connected with a positioning block, and the positioning block is provided with a positioning through hole matched with the corresponding side guide column; the inner side surface of the positioning through hole is uniformly provided with balls. The invention mainly aims to provide the punching machine, so that the consumption of steel of the punching machine is reduced, and the production cost is greatly reduced. Based on the above, the existing freezer dry filter needs to flatten the copper pipe firstly during stamping, then inserts the mold core into the flattened pipe section of the copper pipe, and stamps the copper pipe through the upper and lower molds, which can be completed only by stamping for many times, and has troublesome operation and low working efficiency, and meanwhile, the manual feeding has certain danger; therefore, the existing requirements are not met, and an electric automatic refrigerator double-tail filter production tail stamping device is provided for the electric automatic refrigerator double-tail filter production.

Disclosure of Invention

The invention aims to provide a tail punching device for producing an electric automatic freezer double-tail filter, which solves the problems that the existing freezer dry filter provided by the background technology needs to flatten a copper pipe firstly during punching, then inserts a mold core into the flattened pipe section of the copper pipe, and punches the copper pipe through an upper mold and a lower mold, so that the operation can be completed only by punching for many times, the operation is troublesome, the working efficiency is low, and meanwhile, the manual feeding has certain danger.

In order to achieve the purpose, the invention provides the following technical scheme: a tail punching device for the production of an electric automatic freezer double-tail filter comprises a machine body main body; the rear end face of the top of the machine body main body is fixedly connected with a group of driving motors; a group of stamping connecting rods are hinged on a rotating shaft of the driving motor; the inner side of the upper part of the machine body main body is connected with a group of upper punch blocks in a sliding manner; the top of the upper punch block is hinged with the bottom of the punch connecting rod; the inner side of the lower part of the machine body main body is connected with a group of lower punch blocks in a sliding manner; a group of stamping intermediate gears is rotatably connected inside the rear end face of the machine body main body; a group of die core blocks are connected to the rear part of the left side of the machine body main body in a sliding manner in the front-back direction; a group of mold core middle transmission shafts are axially connected in the rear of the machine body main body; a group of feed driving shafts is rotatably connected to the rear part of the top of the machine body main body; the front end face of the machine body main body is provided with a group of pressing transmission devices and a group of conveying belt devices; and a group of conveyor belt driving shafts are rotatably connected to the rear part of the lower part of the machine body main body.

Preferably, the driving motor further comprises a stamping oscillating crankshaft, a group of stamping oscillating crankshafts is arranged on a rotating shaft of the driving motor, a stamping connecting rod is hinged with the stamping oscillating crankshafts, and a crank-slider mechanism is formed by the stamping oscillating crankshafts, the stamping connecting rod, the upper stamping block and the machine body.

Preferably, the upper punch block further comprises a lower punch driving rack, the rear end face of the upper punch block is fixedly connected with a group of lower punch driving racks, and the lower punch driving racks and the punch intermediate gear are meshed to form a gear rack transmission mechanism together.

Preferably, the lower punch block further comprises a lower punch driven rack, the rear end face of the lower punch block is fixedly connected with a group of lower punch driven racks, and the lower punch driven racks and the punch intermediate gear are meshed to form a gear rack transmission mechanism together.

Preferably, the upper punch block further comprises a mold core driving rack, the rear portion of the upper punch block is fixedly connected with a group of mold core driving racks, the mold core intermediate transmission shaft further comprises a mold core intermediate gear, two groups of mold core intermediate gears are coaxially and fixedly connected to the mold core intermediate transmission shaft, and the mold core intermediate gear and the mold core driving racks are meshed to form a gear rack transmission mechanism together.

Preferably, the die core block further comprises a die core driven rack, a group of die core driven racks are fixedly connected to the rear of the die core block, and a die core intermediate gear is meshed with the die core driven racks to form a gear rack transmission mechanism together.

Preferably, the driving motor further comprises a feeding driving gear, a group of feeding driving gears is coaxially and fixedly connected to a rotating shaft of the driving motor, the feeding driving gear is an incomplete gear, the feeding driving shaft further comprises a feeding driven gear, a group of feeding driven gears is coaxially and fixedly connected to a front end face of the feeding driving shaft, and the feeding driven gear are meshed to form an incomplete gear transmission mechanism.

Preferably, the feeding driving shaft further comprises a feeding driving belt wheel, a group of feeding driving belt wheels is coaxially and fixedly connected with the rear end face of the feeding driving shaft, the pressing driving device is a conveying belt structure, the machine body further comprises a pressing auxiliary plate, a group of pressing auxiliary plates are arranged in the middle of the machine body, the pressing auxiliary plates are located in the middle of the pressing driving device, the pressing driving device further comprises a pressing driven belt wheel, a group of pressing driven belt wheels are coaxially and fixedly connected with a driving wheel of the pressing driving device, and a group of synchronous driving belts are wound on the outer sides of the pressing driven belt wheel and the feeding driving belt wheel together to form a synchronous driving belt driving mechanism.

Preferably, the conveyer belt drive shaft is still including the conveyer belt driving pulley, and the coaxial fixedly connected with of the rear end face of conveyer belt drive shaft has a set of conveyer belt driving pulley, and the outside that compresses tightly driven pulley and conveyer belt driving pulley twines a set of synchronous drive belt jointly and constitutes synchronous drive belt drive mechanism jointly.

Preferably, the conveyor belt driving shaft further comprises a conveyor belt driving gear, a group of conveyor belt driving gears are coaxially and fixedly connected with the front end face of the conveyor belt driving shaft, the conveyor belt device further comprises a conveyor belt driven gear, a group of conveyor belt driven gears are coaxially and fixedly connected with the rear portion of the driving gear of the conveyor belt device, the conveyor belt driving gear and the conveyor belt driven gear are meshed to form a gear transmission mechanism together, the conveyor belt device further comprises a filter bearing device, and a plurality of groups of filter bearing devices are uniformly arranged on the conveyor belt of the conveyor belt device.

Preferably, the upper punch block further comprises a punching die, and two groups of punching dies are arranged on the upper punch block and the lower punch block respectively.

Compared with the prior art, the invention has the beneficial effects that:

the device realizes automatic feeding and compaction of the filter by adopting an incomplete gear transmission mechanism, a synchronous transmission belt transmission mechanism and a gear transmission mechanism, and is convenient for punching the filter; meanwhile, the upper punch block slides up and down by adopting a crank-slider mechanism, the die core block slides back and forth by linking the die core block through the gear-rack transmission mechanism, the die core block is inserted into the filter, and the upper punch block slides up and down and simultaneously links the lower punch block to slide up and down through the gear-rack transmission mechanism to complete the punching action.

The device has changed in the past and need manual material loading many times just can accomplish the problem of punching press, only need place the filter and bear the device on and can accomplish, a series of actions such as punching press, mold core insert, secondary punching press, very big simplification the operation, great improvement work efficiency, keep away from the work position in the use, the security is higher.

Drawings

FIG. 1 is a schematic side view of the present invention;

FIG. 2 is a schematic side view of the internal drive shaft of the present invention;

FIG. 3 is a schematic side view of the internal transmission rear axle of the present invention;

FIG. 4 is a schematic diagram of a transmission shaft side structure of the conveyor belt device of the present invention;

fig. 5 is a schematic view of the upper punch block of the present invention in a shaft side structure;

FIG. 6 is a schematic side view of the transmission shaft of the lower punch press of the present invention;

FIG. 7 is a schematic side view of a mold core block drive shaft of the present invention;

FIG. 8 is a schematic side view of the driving motor shaft of the present invention;

in the figure: 1. a main body of the body; 101. pressing the auxiliary plate; 2. a drive motor; 201. a feed drive gear; 202. stamping a swing crankshaft; 3. stamping a connecting rod; 4. punching a block; 401. the rack is driven by downward stamping; 402. the mold core drives the rack; 403. a stamping die; 5. punching a pressing block downwards; 501. the driven rack is pressed downwards; 6. stamping the intermediate gear; 7. a mold core middle transmission shaft; 701. a mold core intermediate gear; 8. a die core block; 801. a mold core driven rack; 9. a feed drive shaft; 901. a feed drive pulley; 902. a feed driven gear; 10. a compression transmission; 1001. compressing the driven belt wheel; 11. a conveyor means; 1101. a conveyor belt driven gear; 1102. a filter carrier; 12. a conveyor drive shaft; 1201. a belt drive gear; 1202. the conveyor belt drives the belt pulley.

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.

Referring to fig. 1 to 8, an embodiment of the present invention includes: a tail punching device for the production of an electric automatic freezer double-tail filter comprises a machine body main body 1; the rear end face of the top of the machine body main body 1 is fixedly connected with a group of driving motors 2; the driving motor 2 further comprises a stamping swing crankshaft 202, a group of stamping swing crankshafts 202 are arranged on a rotating shaft of the driving motor 2, the stamping connecting rod 3 is hinged with the stamping swing crankshafts 202, the stamping connecting rod 3, the upper stamping block 4 and the machine body main body 1 jointly form a crank block mechanism, and the driving motor 2 drives the upper stamping block 4 to slide up and down through the crank block mechanism to perform stamping action in use; the driving motor 2 further comprises a feeding driving gear 201, a group of feeding driving gears 201 are coaxially and fixedly connected to a rotating shaft of the driving motor 2, the feeding driving gear 201 is an incomplete gear, the feeding driving shaft 9 further comprises a feeding driven gear 902, a group of feeding driven gears 902 are coaxially and fixedly connected to the front end face of the feeding driving shaft 9, the feeding driven gears 902 and the feeding driven gears 902 are meshed to form an incomplete gear transmission mechanism together, and the driving motor 2 drives the feeding driving shaft 9 to intermittently rotate through the incomplete gear transmission mechanism in use; a group of stamping connecting rods 3 are hinged on a rotating shaft of the driving motor 2; the inner side of the upper part of the machine body main body 1 is connected with a group of upper punch blocks 4 in a sliding way; the upper punching block 4 further comprises a mold core driving rack 402, the rear part of the upper punching block 4 is fixedly connected with a group of mold core driving racks 402, the mold core intermediate transmission shaft 7 further comprises a mold core intermediate gear 701, the mold core intermediate transmission shaft 7 is coaxially and fixedly connected with two groups of mold core intermediate gears 701, the mold core intermediate gears 701 and the mold core driving racks 402 are meshed to form a gear and rack transmission mechanism together, and when the upper punching block 4 slides downwards in use, the upper punching block 4 drives the mold core intermediate transmission shaft 7 to rotate through the gear and rack transmission mechanism; the upper punch block 4 further comprises a lower punch driving rack 401, the rear end face of the upper punch block 4 is fixedly connected with a group of lower punch driving racks 401, the lower punch driving racks 401 and the punch intermediate gear 6 are meshed to form a gear and rack transmission mechanism together, when the upper punch block 4 slides up and down, the upper punch block 4 drives the punch intermediate gear 6 to rotate through the gear and rack transmission mechanism; the top of the upper punch block 4 is hinged with the bottom of the punch connecting rod 3; the inner side of the lower part of the machine body main body 1 is connected with a group of lower punch blocks 5 in a sliding way; the lower punch block 5 further comprises a lower punch driven rack 501, the rear end face of the lower punch block 5 is fixedly connected with a group of lower punch driven racks 501, the lower punch driven racks 501 and the punch intermediate gear 6 are meshed to form a gear and rack transmission mechanism together, when the punch intermediate gear 6 rotates in use, the punch intermediate gear 6 drives the lower punch block 5 to slide up and down through the gear and rack transmission mechanism, and the punch intermediate gear is matched with the upper punch block 4 to complete a punching action; a group of stamping intermediate gears 6 are rotatably connected inside the rear end surface of the machine body main body 1; a group of die core blocks 8 are connected with the left rear part of the machine body main body 1 in a sliding manner in the front-back direction; the die core block 8 also comprises a die core driven rack 801, a group of die core driven racks 801 are fixedly connected to the rear part of the die core block 8, a die core intermediate gear 701 and the die core driven racks 801 are meshed to form a gear rack transmission mechanism together, when the die core intermediate transmission shaft 7 rotates in use, the die core intermediate transmission shaft 7 drives the die core block 8 to slide back and forth through the gear rack transmission mechanism, and the die core block 8 is inserted into the filter; a group of mold core middle transmission shafts 7 are axially connected in the rear of the machine body main body 1; a group of feed driving shafts 9 are rotatably connected to the rear part of the top of the machine body main body 1; the feeding driving shaft 9 further comprises a feeding driving belt wheel 901, the rear end face of the feeding driving shaft 9 is coaxially and fixedly connected with a group of feeding driving belt wheels 901, the pressing transmission device 10 is a conveying belt structure, the machine body 1 further comprises a pressing auxiliary plate 101, the middle part of the machine body 1 is provided with a group of pressing auxiliary plate 101, the pressing auxiliary plate 101 is positioned in the middle part of the pressing transmission device 10, the pressing transmission device 10 further comprises a pressing driven belt wheel 1001, a driving wheel of the pressing transmission device 10 is coaxially and fixedly connected with a group of pressing driven belt wheels 1001, a group of synchronous driving belts are wound on the outer sides of the pressing driven belt wheels and the feeding driving belt wheels 901 to form a synchronous driving belt transmission mechanism, and when the feeding driving shaft 9 rotates, the feeding driving shaft 9 drives the pressing transmission device 10 to synchronously rotate through; the front end surface of the machine body main body 1 is provided with a group of pressing transmission devices 10 and a group of conveying belt devices 11; a group of conveyor belt driving shafts 12 are rotatably connected to the rear part of the lower part of the machine body main body 1; the conveyor belt driving shaft 12 further comprises a conveyor belt driving pulley 1202, a group of conveyor belt driving pulleys 1202 is coaxially and fixedly connected to the rear end face of the conveyor belt driving shaft 12, a group of synchronous belts are wound on the outer sides of the pressing driven pulley 1001 and the conveyor belt driving pulley 1202 to form a synchronous belt driving mechanism, and when the pressing driving device 10 rotates in use, the pressing driving device 10 drives the conveyor belt driving shaft 12 to synchronously rotate through the synchronous belt driving mechanism; the conveyor belt driving shaft 12 further comprises a conveyor belt driving gear 1201, a group of conveyor belt driving gears 1201 are coaxially and fixedly connected to the front end face of the conveyor belt driving shaft 12, the conveyor belt device 11 further comprises a conveyor belt driven gear 1101, a group of conveyor belt driven gears 1101 are coaxially and fixedly connected to the rear portion of the driving wheel of the conveyor belt device 11, the conveyor belt driving gear 1201 and the conveyor belt driven gears 1101 are meshed to form a gear transmission mechanism together, the conveyor belt device 11 further comprises a filter bearing device 1102, a plurality of groups of filter bearing devices 1102 are uniformly arranged on the conveyor belt of the conveyor belt device 11, in use, the filter is positioned and supported through the filter bearing devices 1102, when the conveyor belt driving shaft 12 rotates, the conveyor belt driving shaft 12 drives the conveyor belt device 11 to.

Further, the upper punch 4 further comprises a punching die 403, two groups of punching dies 403 are arranged on the upper punch 4 and the lower punch 5, and in use, the copper pipe is firstly flattened through the punching die 403 on the right side, and then the end of the copper pipe is pressed into a double-tail structure together with the punching die 403 on the left side.

The working principle is as follows: when the filter pressing device is used, a filter is placed on the filter bearing device 1102, the driving motor 2 drives the feeding driving shaft 9 to intermittently rotate through the incomplete gear transmission mechanism, when the feeding driving shaft 9 rotates, the feeding driving shaft 9 drives the pressing transmission device 10 to synchronously rotate through the synchronous transmission belt transmission mechanism, the pressing transmission device 10 drives the conveyor belt driving shaft 12 to synchronously rotate through the synchronous transmission belt transmission mechanism, the conveyor belt driving shaft 12 drives the conveyor belt device 11 to rotate through the gear transmission mechanism, the feeding action of the filter is completed, and meanwhile, the filter is fixed on the conveyor belt device 11 through the extrusion of the pressing auxiliary plate 101 and the pressing transmission device 10; meanwhile, the driving motor 2 drives the upper punch block 4 to slide up and down through the crank-slider mechanism, the upper punch block 4 drives the die core intermediate transmission shaft 7 to rotate through the rack-and-pinion transmission mechanism, the die core intermediate transmission shaft 7 drives the die core block 8 to slide back and forth through the rack-and-pinion transmission mechanism, the die core block 8 is inserted into the filter, the upper punch block 4 continues to slide down, the upper punch block 4 drives the punch intermediate gear 6 to rotate through the rack-and-pinion transmission mechanism, the punch intermediate gear 6 drives the lower punch block 5 to slide up and down through the rack-and-pinion transmission mechanism, the punch action is completed by matching with the upper punch block 4, the copper pipe is firstly flattened through the left and right.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The utility model provides an afterbody stamping device of two tail filter productions of electric automatization refrigerator-freezer which characterized in that: comprises a main body (1); the rear end face of the top of the machine body main body (1) is fixedly connected with a group of driving motors (2); a rotating shaft of the driving motor (2) is hinged with a group of stamping connecting rods (3); the inner side of the upper part of the machine body main body (1) is connected with a group of upper punch blocks (4) in a sliding manner; the top of the upper punch block (4) is hinged with the bottom of the punch connecting rod (3); the inner side of the lower part of the machine body main body (1) is connected with a group of lower punch blocks (5) in a sliding manner; a group of stamping intermediate gears (6) are rotatably connected inside the rear end face of the machine body main body (1); a group of die core blocks (8) are connected to the rear part of the left side of the machine body main body (1) in a sliding manner in the front-rear direction; a group of mold core middle transmission shafts (7) are axially connected in the rear of the machine body main body (1); a group of feed driving shafts (9) are rotatably connected to the rear part of the top of the machine body main body (1); the front end face of the machine body main body (1) is provided with a group of pressing transmission devices (10) and a group of conveying belt devices (11); the rear part of the lower part of the machine body main body (1) is rotatably connected with a group of conveyor belt driving shafts (12).

2. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the driving motor (2) further comprises a stamping swing crankshaft (202), a group of stamping swing crankshafts (202) are arranged on a rotating shaft of the driving motor (2), a stamping connecting rod (3) is hinged with the stamping swing crankshafts (202), and a crank block mechanism is formed among the stamping swing crankshafts (202), the stamping connecting rod (3), the upper stamping block (4) and the machine body (1) together.

3. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the upper punch block (4) further comprises a lower punch driving rack (401), the rear end face of the upper punch block (4) is fixedly connected with a group of lower punch driving racks (401), and the lower punch driving racks (401) and the punch intermediate gear (6) are meshed to form a gear rack transmission mechanism together; the upper punch block (4) further comprises a punching die (403), and two groups of punching dies (403) are arranged on the upper punch block (4) and the lower punch block (5).

4. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the lower punch block (5) further comprises a lower punch driven rack (501), the rear end face of the lower punch block (5) is fixedly connected with a group of lower punch driven racks (501), and the lower punch driven racks (501) and the punch intermediate gear (6) are meshed to form a gear rack transmission mechanism together.

5. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the upper punch block (4) further comprises a mold core driving rack (402), the rear portion of the upper punch block (4) is fixedly connected with a group of mold core driving racks (402), the mold core intermediate transmission shaft (7) further comprises a mold core intermediate gear (701), two groups of mold core intermediate gears (701) are coaxially and fixedly connected to the mold core intermediate transmission shaft (7), and the mold core intermediate gear (701) and the mold core driving racks (402) are meshed to form a gear-rack transmission mechanism together.

6. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the die core block (8) further comprises a die core driven rack (801), a group of die core driven racks (801) are fixedly connected to the rear of the die core block (8), and a die core intermediate gear (701) is meshed with the die core driven racks (801) to form a gear-rack transmission mechanism together.

7. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the driving motor (2) further comprises a feeding driving gear (201), a group of feeding driving gears (201) is coaxially and fixedly connected to a rotating shaft of the driving motor (2), the feeding driving gears (201) are incomplete gears, the feeding driving shaft (9) further comprises a feeding driven gear (902), a group of feeding driven gears (902) are coaxially and fixedly connected to the front end face of the feeding driving shaft (9), and the feeding driven gear (902) are meshed to form an incomplete gear transmission mechanism.

8. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the feeding driving shaft (9) further comprises a feeding driving belt wheel (901), the rear end face of the feeding driving shaft (9) is coaxially and fixedly connected with a group of feeding driving belt wheels (901), the pressing transmission device (10) is a conveying belt structure, the machine body main body (1) further comprises a pressing auxiliary plate (101), the middle of the machine body main body (1) is provided with a group of pressing auxiliary plate (101), the pressing auxiliary plate (101) is located in the middle of the pressing transmission device (10), the pressing transmission device (10) further comprises a pressing driven belt wheel (1001), a group of pressing driven belt wheels (1001) is coaxially and fixedly connected to a driving wheel of the pressing transmission device (10), and a group of synchronous driving belts are wound on the outer sides of the pressing driven belt wheels (1001) and the feeding driving belt wheels (901) to form a synchronous driving belt transmission mechanism.

9. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the belt driving shaft (12) further comprises a belt driving belt wheel (1202), the rear end face of the belt driving shaft (12) is coaxially and fixedly connected with a group of belt driving belt wheels (1202), and a group of synchronous belts are wound on the outer sides of the pressing driven belt wheel (1001) and the belt driving belt wheels (1202) together to form a synchronous belt transmission mechanism.

10. The tail stamping device for the production of an electrically automated bin double-tail filter according to claim 1, wherein: the belt conveyor driving shaft (12) is characterized by further comprising a belt conveyor driving gear (1201), a group of belt conveyor driving gears (1201) is fixedly connected with the front end face of the belt conveyor driving shaft (12) in a coaxial mode, the belt conveyor device (11) is further comprising a belt conveyor driven gear (1101), a group of belt conveyor driven gear (1101) is fixedly connected with the rear portion of the driving wheel of the belt conveyor device (11) in a coaxial mode, the belt conveyor driving gear (1201) and the belt conveyor driven gear (1101) are meshed to form a gear transmission mechanism together, the belt conveyor device (11) is further comprising a filter bearing device (1102), and a plurality of groups of filter bearing devices (1102) are evenly arranged on.

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