CN109107963B - Rotary dynamic sterilizing cabinet for cleaning rubber plugs - Google Patents

Abstract

The invention discloses a rotary dynamic sterilization cabinet for cleaning rubber plugs, which comprises: the sterilizing device comprises a shell, wherein a frame and a groove-shaped guide rail are arranged in the shell, the frame is movably arranged in the groove-shaped guide rail, a limiting device is arranged between the frame and the groove-shaped guide rail, a supporting seat and a supporting wheel are arranged on the frame, a spiral guide groove is arranged on the inner wall of a sterilizing cylinder, a material opening and a rotating shaft are arranged on the sterilizing cylinder, the sterilizing cylinder is placed on the supporting wheel, the rotating shaft is connected with the supporting seat in a matched manner, a sealing door is arranged on the shell on the same side of the material opening, a discharging cavity is arranged on the inner wall of the sealing door, when the sealing door is closed with the shell, and the frame is positioned on a working station, the material opening on the sterilizing cylinder just stretches into the discharging cavity, a discharging pipe is arranged at the bottom of the discharging cavity, and a driving component capable of driving the sterilizing cylinder to rotate is arranged between the shell and the sterilizing cylinder. The invention has the advantages of high cleaning efficiency and automatic discharging.

Description

Rotary dynamic sterilizing cabinet for cleaning rubber plugs

Technical Field

The invention relates to a sterilizing cabinet, in particular to a rubber plug sterilizing cabinet.

Background

After the rubber plug is produced or recovered, the rubber plug needs to be cleaned, so that the safety can be ensured. At present, most of vacuum defoamation rubber plug cleaning machines are used for cleaning rubber plugs, when the vacuum defoamation rubber plug cleaning machines are used for cleaning, a large amount of clear water is needed to be added into the cleaning machines, then the rubber plugs are placed into the cleaning machines, after the rubber plugs enter the clear water, small particles adhered to the rubber plugs are adsorbed by water to form small bubbles due to the hydrophobicity of the surfaces of the rubber plugs and the tension effect of the water, then air in the cleaning machines is pumped out to form a vacuum environment, then the bubbles adhered to the rubber plugs are defoamed by utilizing a vacuum principle, so that particles and impurities adhered to the rubber plugs are dispersed into the water after being separated from the surfaces of the rubber plugs, and therefore, the rubber plug cleaning machines can clean the rubber plugs, and workers can take out the rubber plugs from the water. However, when the vacuum defoaming rubber plug cleaning machine is used, an evacuating machine is additionally arranged, and impurities attached to the air bubbles are easy to secondarily adhere to the rubber plug during vacuum defoaming, so that the cleaning quality is affected; and after the cleaning is finished, a worker is required to manually take out the rubber plug from the machine body, so that the rubber plug is very inconvenient, and the working efficiency is reduced.

Disclosure of Invention

The invention aims to provide a rotary dynamic sterilizing cabinet which is high in cleaning efficiency and capable of automatically discharging and is used for cleaning rubber plugs.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows: a rotary dynamic sterilization cabinet for cleaning rubber plugs, comprising: the device comprises a shell, wherein a frame is arranged in the shell, a plurality of rollers are arranged on two sides of the bottom of the frame, two groove-shaped guide rails are arranged in the shell, the rollers on two sides of the frame are respectively placed in the two groove-shaped guide rails, a limiting device is arranged between the frame and the groove-shaped guide rails, the limiting device can limit the frame on a working station, a sterilizing cylinder body is movably supported on the frame, a filtering hole is formed in the side wall of the sterilizing cylinder body, a spiral guide groove capable of guiding materials to enter and exit the sterilizing cylinder body is arranged on the inner wall of the sterilizing cylinder body, a material port used for feeding and discharging is formed in one end of the sterilizing cylinder body, and the specific connection structure between the frame and the sterilizing cylinder body is as follows: a supporting seat is arranged at one end of the frame, and two supporting wheels are respectively arranged at two sides of the bottom of the other end of the frame; a rotary shaft is arranged on the bottom of the other end of the sterilizing cylinder, the rotary shaft on the sterilizing cylinder is connected with the supporting seat in a matched manner and can rotate on the supporting seat, the sterilizing cylinder is placed on the two supporting wheels, and the two supporting wheels can be driven to rotate together when the sterilizing cylinder rotates; a sealing door is arranged on the shell positioned on the same side of the material opening, a discharging cavity is arranged on the inner wall of the sealing door, when the sealing door is closed with the shell and the frame is positioned on a working station, the material opening on the sterilizing cylinder body just stretches into the discharging cavity on the sealing door, a discharging pipe is arranged at the bottom of the discharging cavity, and extends outwards after penetrating through the sealing door downwards, and a butterfly valve is arranged on the discharging pipe extending out of the sealing door; a driving component is arranged between the shell and the sterilizing cylinder, the driving component can drive the sterilizing cylinder to rotate around the central axis of the sterilizing cylinder on the frame, when the sterilizing cylinder rotates positively, materials can gradually move into the sterilizing cylinder from the material port along the spiral material guide groove, and when the sterilizing cylinder rotates reversely, the materials in the sterilizing cylinder can gradually move towards the material port along the spiral material guide groove; a water delivery pipe is fixedly arranged on the frame, a high Wen Penlin pipe is connected on the water delivery pipe, a through hole is formed in a rotating shaft of the sterilization cylinder, a sealing bearing is arranged in the through hole, and the high Wen Penlin pipe penetrates through the sealing bearing and then stretches into an inner cavity of the sterilization cylinder.

Further, the foregoing rotary dynamic sterilization cabinet for cleaning rubber plugs, wherein the driving assembly comprises: the sterilization device comprises a shell, a servo motor, a transmission gear and a gear ring, wherein the servo motor is fixedly arranged in the shell, the transmission gear is fixedly connected to an output shaft of the servo motor, the gear ring is fixedly sleeved on the sterilization barrel, the transmission gear is meshed with the gear ring, the servo motor drives the transmission gear to rotate, and the gear ring drives the sterilization barrel to rotate on the frame through the gear transmission function.

Further, the rotary dynamic sterilization cabinet for cleaning the rubber plug, wherein the specific structure of the limiting device is as follows: a first stop block and a second stop block are respectively arranged on two sides of the front end and the rear end of the groove-shaped guide rail, wherein the first stop block is positioned on one side close to the material opening, the second stop block is positioned on one side close to the barrel bottom, a first stop block and a second stop block which can be respectively matched with the first stop block and the second stop block are arranged on the frame, the second stop block is fixedly arranged at the bottom of the frame, the rear end of the first stop block is hinged on a mounting plate fixed at the bottom of the frame, a limiting pin is arranged at the front end of the first stop block, a vertically long-strip-shaped hole is arranged at the front end of the mounting plate, the limiting pin is movably arranged in the long-strip-shaped hole in a penetrating manner, and when the front end of the first stop block rotates up and down around a hinge point of the limiting pin, the limiting pin moves up and down in the long-strip-shaped hole; when the frame pushes into the shell, the first limiting block is contacted with the first stop block, the front end of the first limiting block rotates upwards around the hinge point of the first limiting block under the pushing action of the first stop block, so that the first limiting block can clear the first stop block, when the frame reaches a working station, the second limiting block can lean against the front end of the second stop block, and after the front end of the first limiting block passes over the first stop block, the front end of the first limiting block falls under the action of dead weight and carries with the limiting pin, so that the front end of the first limiting block just leans against the rear end of the first stop block, and at the moment, the limiting pin falls at the bottom of the long-strip-shaped hole, so that the frame is limited on the working station; when the frame is required to be pulled out, the frame can be pulled out after the first limiting block is lifted upwards to be higher than the first stop block.

Further, the rotary dynamic sterilization cabinet for cleaning the rubber plug, wherein the specific connection structure between the supporting wheel and the frame is as follows: the two sides of the frame are respectively fixedly provided with a T-shaped groove track, each T-shaped groove track is movably provided with a supporting wheel frame, each supporting wheel frame can move in the corresponding T-shaped groove track, two supporting wheels are respectively hinged on the two supporting wheel frames, each T-shaped groove track is respectively transversely provided with a thick plate, each thick plate is provided with two threaded through holes, the two threaded through holes on each thick plate are aligned with the supporting wheel frames in the corresponding T-shaped groove tracks, each threaded through hole is in threaded connection with a screw rod, the top ends of the screw rods penetrate through the thick plates connected with each other and then are propped against the supporting wheel frames, and each screw rod is respectively provided with a locking nut.

Further, the rotary dynamic sterilization cabinet for cleaning the rubber plugs is characterized in that annular grooves are formed in the two supporting wheels, annular wheels protruding out of the sterilization cylinder are arranged on the outer side of the sterilization cylinder, and the annular wheels extend into the annular grooves in the two supporting wheels.

Further, the rotary dynamic sterilization cabinet for cleaning the rubber plug comprises a support seat and a frame, wherein the support seat is in a concrete connection structure: a trapezoid support is fixedly arranged on the frame, and two through holes are formed in a cross bar at the upper part of the trapezoid support; the bottom of the supporting seat is provided with two threaded holes, the supporting seat is sleeved on the cross rod of the trapezoid bracket, the two threaded holes on the supporting seat are aligned with the two through holes on the cross rod respectively, and the two bolts respectively penetrate through the two through holes on the cross rod and then are screwed with the two threaded holes on the supporting seat to be fixed, so that the supporting seat is fixed on the trapezoid bracket.

Further, the rotary dynamic sterilization cabinet for cleaning the rubber plug is characterized in that a connecting rod is arranged between waist bars on two sides of the trapezoid support, a connecting plate is fixedly arranged on the connecting rod, an arc-shaped groove capable of clamping the water supply pipe is arranged at the outer end of the connecting plate, and an arc-shaped pipe clamping ring is fixedly arranged on the arc-shaped groove after the water supply pipe is clamped in the arc-shaped groove, so that the water supply pipe is fixed on the connecting plate.

Further, the rotary dynamic sterilization cabinet for cleaning the rubber plug, wherein the specific connection structure between the supporting seat and the sterilization cylinder is as follows: the sterilizing device comprises a sterilizing cylinder body, a supporting seat, a rotating shaft, a connecting hole, a limiting screw, a rotating shaft and a limiting screw, wherein the connecting hole is formed in the supporting seat, two bearings are fixedly arranged in the connecting hole, the rotating shaft on the sterilizing cylinder body is arranged in the two bearings in a penetrating mode and extends out of the supporting seat, two threaded holes are formed in the rotating shaft extending out of the supporting seat, the limiting screw protruding outwards from the rotating shaft is respectively connected in the two threaded holes, and the rotating shaft can be prevented from being separated from the bearings.

Further, the rotary dynamic sterilizing cabinet for cleaning the rubber plug is characterized in that a sewage draining groove is arranged in the shell below the sterilizing cylinder.

The invention has the advantages that: when the sterilization cylinder rotates forward, the rubber plug rolls in the sterilization cylinder, the rubber plug collides with each other in the rolling process to form vibration, particles and impurities attached to the surface of the rubber plug are easy to loosen in the vibration process, then the particles and impurities on the surface of the rubber plug are washed and fall off after being continuously washed by high-temperature water in a high Wen Penlin pipe, finally the particles and impurities are taken away by water flow, the rubber plug can be sterilized by high-temperature water in the continuous spraying process, after the cleaning and sterilization are finished, the rubber plug can move along the spiral guide groove from the sterilization cylinder to the direction of a material outlet along the spiral guide groove, in the process, the water attached to the rubber plug can be separated from the surface of the rubber plug under the action of centrifugal force and flows out from the filter hole, the dehydrated rubber plug can continuously enter a discharging cavity on a sealing door through the material outlet, and then the discharging pipe is used for discharging, and the working efficiency of discharging is greatly improved.

Drawings

Fig. 1 is a schematic structural view of a rotary dynamic sterilization cabinet for cleaning rubber plugs according to the present invention.

Fig. 2 is a schematic view of a part of the structure in the direction a in fig. 1.

Fig. 3 is a schematic structural view of a limiting device in a rotary dynamic sterilization cabinet for cleaning rubber plugs.

Fig. 4 is a schematic structural view of a connection structure between a support wheel and a frame in a rotary dynamic sterilization cabinet for cleaning rubber plugs according to the present invention.

Detailed Description

The technical scheme of the invention is further described below with reference to the attached drawings and the preferred embodiments.

As shown in fig. 1, 2, 3 and 4, the rotary dynamic sterilization cabinet for cleaning rubber plugs according to the present invention comprises: the sterilizing device comprises a shell 1, wherein a frame 2 is arranged in the shell 1, two rollers 21 are respectively arranged on two sides of the bottom of the frame 2, two groove-shaped guide rails 11 are arranged in the shell 1, the rollers 21 on two sides of the frame 2 are respectively placed in the two groove-shaped guide rails 11 and can move in the groove-shaped guide rails 11, a limiting device is arranged between the frame 2 and the groove-shaped guide rails 11, the frame 2 can be limited on a working station by the limiting device, a sterilizing cylinder 3 is movably supported on the frame 2, filtering holes are formed in the side wall of the sterilizing cylinder 3, a spiral guide groove 31 capable of guiding materials to enter and exit the sterilizing cylinder 3 is formed in the inner wall of the sterilizing cylinder 3, a material inlet 32 for feeding and discharging is formed in one end of the sterilizing cylinder 3, and a pollution discharge groove is formed in the shell 1 below the sterilizing cylinder 3. The specific connection structure between the frame 2 and the sterilizing cylinder 3 is as follows: a supporting seat 23 is arranged at the rear end of the frame 2, a connecting hole is formed in the supporting seat 23, two bearings 231 are fixedly arranged in the connecting hole, and two supporting wheels 24 capable of adjusting positions are respectively arranged at two sides of the bottom of the front end of the frame 2; the rotary shaft 33 is arranged on the bottom of the other end of the sterilization barrel 3, the rotary shaft 33 is arranged in the two bearings 231 in a penetrating way and extends outwards from the supporting seat 23, two threaded holes are arranged on the rotary shaft 33 extending out of the supporting seat 23, a limiting screw 331 protruding outwards from the rotary shaft 33 is respectively connected in the two threaded holes, and the limiting screw 331 can prevent the rotary shaft 33 from being separated from the bearings 231. The sterilizing cylinder 3 is placed on the two supporting wheels 24, the supporting wheels 24 can be driven to rotate together when the sterilizing cylinder 3 rotates, the sealing door 18 is arranged on the shell 1 positioned on the same side of the material opening 32, the discharging cavity 181 is arranged on the inner wall of the sealing door 18, when the sealing door 18 is closed with the shell 1 and the frame 2 is positioned on a working station, the material opening 32 on the sterilizing cylinder 3 just stretches into the discharging cavity 181 on the sealing door 18, the bottom of the discharging cavity 181 is provided with a discharging pipe 182, the discharging pipe 182 downwards penetrates through the sealing door 18 and outwards stretches out, and the discharging pipe 182 stretching out of the sealing door 18 is provided with a butterfly valve 183; a drive assembly is provided between the housing 1 and the sterilization cylinder 3, said drive assembly comprising: the sterilization device comprises a servo motor 51, a transmission gear 52 and a gear ring 53, wherein the servo motor 51 is fixedly arranged in a shell 1, the transmission gear 52 is fixedly connected to an output shaft of the servo motor 51, the gear ring 53 is fixedly sleeved on a sterilization barrel 3, the transmission gear 52 is meshed with the gear ring 53, the servo motor 51 drives the transmission gear 52 to rotate, the transmission gear 52 enables the gear ring 53 to drive the sterilization barrel 3 to rotate around a central axis of the machine frame 2 through gear transmission, when the sterilization barrel 3 rotates positively, materials can gradually move into the sterilization barrel 3 from a material port 32 along a spiral material guide groove 31, and when the sterilization barrel 3 rotates reversely, the materials in the sterilization barrel 3 can gradually move towards the material port 32 along the spiral material guide groove 31; the machine frame 2 is fixedly provided with a water delivery pipe 25, the water delivery pipe 25 is connected with a high Wen Penlin pipe 26, a through hole is formed in a rotating shaft 33 of the sterilization barrel 3, a sealing bearing 34 is arranged in the through hole, and the high Wen Penlin pipe 26 penetrates through the through hole in the rotating shaft 33 and the sealing bearing 34 and then stretches into the sterilization barrel 3, so that the high Wen Penlin pipe 26 cannot rotate along with the rotation of the sterilization barrel 3.

When the sterilizing cylinder 3 is in cleaning work, the rubber plug in the sterilizing cylinder 3 rotates positively, the rubber plug rolls in the sterilizing cylinder 3, the rubber plug collides with each other in the rolling process to form vibration, particles and impurities attached to the surface of the rubber plug are easy to loosen in the vibration process, meanwhile, the water supply pipe 25 supplies high-temperature water to the high-temperature spray pipe 26, the high-temperature water is sprayed out of the high-temperature water to continuously wash the rubber plug, so that the particles and impurities on the surface of the rubber plug are washed and fall off by the high-temperature water, the high-temperature water wraps the particles and impurities and flows outwards into the drain tank through the filtering holes on the sterilizing cylinder 3, the rubber plug can not be in secondary contact with dirty water, secondary pollution can not be caused, the high-temperature water can also be utilized for sterilizing the rubber plug in the continuous spraying process, after the cleaning and sterilizing work is finished on the rubber plug, the water supply pipe 25 stops supplying the high-temperature water to the high-temperature spray pipe 26, then the sterilizing cylinder 3 rotates reversely to enable the rubber plug to move along the direction of the material outlet 32 in the sterilizing cylinder 3, the water on the rubber plug is thrown out under the centrifugal force and flows into the drain tank through the filtering holes, the filtering holes are wrapped by the high-temperature water is discharged into the drain tank through the drain tank 32, and the drain hole is discharged into the drain port 181 when the sealing material outlet port is sealed by the sealing material outlet port 32, and the discharging hole is further discharged into the drain hole 182.

In this embodiment, the specific structure of the limiting device is: a first stop block 12 and a second stop block 13 are respectively arranged on two sides of the front end and the rear end of the groove-shaped guide rail 11, wherein the first stop block 12 is positioned on one side close to a material opening 32 of the sterilizing cylinder 3, the second stop block 13 is positioned on one side close to the cylinder bottom of the sterilizing cylinder 3, a first stop block 14 and a second stop block 15 which can be respectively matched with the first stop block 12 and the second stop block 13 are arranged on the frame 2, the second stop block 15 is fixedly arranged at the bottom of the frame 2, the rear end of the first stop block 14 is hinged on a mounting plate 16 fixed at the bottom of the frame 2, a stop pin 17 is arranged at the front end of the first stop block 14, a vertically long-shaped hole 18 is arranged at the front end of the mounting plate 16, the stop pin 17 is movably arranged in the long-shaped hole 18 in a penetrating manner, and when the front end of the first stop block 14 rotates up and down around a hinge point of the first stop block 14, the stop pin 17 moves up and down in the long-shaped hole 18; when the frame 2 is pushed into the shell 1, the first limiting block 14 is contacted with the first stop block 12, under the pushing action of the first stop block 12, the front end of the first limiting block 14 rotates upwards around the hinge point of the first limiting block 14 to enable the first limiting block 14 to avoid the first stop block 12, so that the first limiting block 14 can pass through the first stop block 12, when the frame 2 is pushed onto a working station, the second limiting block 15 abuts against the front end of the second stop block 13, and after passing through the first stop block 12, the front end of the first limiting block 14 falls down with the limiting pin 17 under the action of dead weight, so that the front end of the first limiting block 14 just abuts against the rear end of the first stop block 12, and at the moment, the limiting pin 17 falls at the bottom of the long-strip-shaped hole 18, so that the frame 2 is limited on the working station; when the frame 2 needs to be pulled out, the frame 2 can be pulled out only by lifting the first limiting block 14 upwards to be higher than the first stop block 12.

In this embodiment, the specific connection structure between the supporting seat 23 and the frame 2 is: a trapezoid support 4 is fixedly arranged on the frame 2, and two through holes are formed in a cross bar 41 at the upper part of the trapezoid support 4; two threaded holes are formed in the bottom of the supporting seat 23, the supporting seat 23 is sleeved on the cross rod 41 of the trapezoid support 4, the two threaded holes in the supporting seat 23 are aligned with the two through holes in the cross rod 41 respectively, and two bolts 42 penetrate through the two through holes in the cross rod 41 respectively and then are screwed with the two threaded holes in the supporting seat 23 to be fixed, so that the supporting seat 23 is fixed on the trapezoid support 4. A connecting rod 44 is arranged between waist bars 43 on two sides of the trapezoid support 4, a connecting plate 45 is fixedly arranged on the connecting rod 44, an arc-shaped groove capable of clamping the water supply pipe 25 is arranged at the outer end of the connecting plate 45, and an arc-shaped pipe clamping ring 46 is fixedly arranged on the arc-shaped groove after the water supply pipe 25 is clamped in the arc-shaped groove, so that the water supply pipe 25 is fixed on the connecting plate 45, and the water supply pipe 25 can be more firmly fixed on the frame 2 by fixing the water supply pipe 25 on the trapezoid support 4.

In this embodiment, the specific connection structure between the supporting wheel 24 and the frame 2 is: a T-shaped groove track 6 is fixedly arranged on two sides of the frame 2 respectively, a supporting wheel frame 61 is movably arranged in each T-shaped groove track 6, each supporting wheel frame 61 can move in the corresponding T-shaped groove track 6, a supporting wheel 24 is hinged on each supporting wheel frame 61, two thick plates 62 are transversely arranged on each T-shaped groove track 6 respectively, two threaded through holes are formed in each thick plate 62, the two threaded through holes in each thick plate 62 are aligned with the supporting wheel frames 61 in the corresponding T-shaped groove track 6 respectively, a screw 63 is connected in each threaded through hole in a threaded mode respectively, the top ends of the two screws 63 in each thick plate 62 are abutted against the corresponding supporting wheel frame 61 respectively, and a locking nut 64 is arranged on each screw 63 respectively. In order to achieve flexible, impact-free and low-noise meshing operation between the transmission gear 52 and the gear ring 53, the meshing gap between the gear ring 53 and the transmission gear 52 needs to be adjusted, the screws 63 on the T-shaped groove rails 6 on both sides of the rack 2 are rotated, and the two screws 63 push the corresponding supporting wheel frames 61 to gradually move, so that the high sterilization cylinder 3 supported by the two supporting wheels 24 is displaced until the meshing gap between the gear ring 53 and the transmission gear 52 on the sterilization cylinder 3 reaches a reasonable meshing gap, and after adjustment is completed, the locking nuts 64 are screwed until the screws 63 abut against the corresponding thick plates 62, so that the screws 63 are locked.

In this embodiment, the ring grooves 241 are formed on the supporting wheels 24 on both sides of the frame 2, the ring-shaped wheels 37 protruding from the sterilizing cylinder 3 are arranged on the sterilizing cylinder 3, the ring-shaped wheels 37 extend into the two ring grooves 241, and the sterilizing cylinder 3 is placed on the two supporting wheels 24, so that the sterilizing cylinder 3 can be prevented from shaking when rotating on the supporting wheels 24 at high speed.

The invention has the advantages that: when the sterilization cylinder rotates forward, the rubber plug rolls in the sterilization cylinder, the rubber plug collides with each other in the rolling process to form vibration, particles and impurities attached to the surface of the rubber plug are easy to loosen in the vibration process, then the particles and impurities on the surface of the rubber plug are washed and fall off after being continuously washed by high-temperature water in a high Wen Penlin pipe, finally the particles and impurities are taken away by water flow, the rubber plug can be sterilized by high-temperature water in the continuous spraying process, after the cleaning and sterilization are finished, the rubber plug can move along the spiral guide groove from the sterilization cylinder to the direction of a material outlet along the spiral guide groove, in the process, the water attached to the rubber plug can be separated from the surface of the rubber plug under the action of centrifugal force and flows out from the filter hole, the dehydrated rubber plug can continuously enter a discharging cavity on a sealing door through the material outlet, and then the discharging pipe is used for discharging, and the working efficiency of discharging is greatly improved.

Claims (7)

1. A rotary dynamic sterilization cabinet for cleaning rubber plugs, comprising: casing, its characterized in that: the machine frame is arranged in the shell, a plurality of rollers are arranged on two sides of the bottom of the machine frame, two groove-shaped guide rails are arranged in the shell, the rollers on two sides of the machine frame are respectively placed in the two groove-shaped guide rails, a limiting device is arranged between the machine frame and the groove-shaped guide rails, the machine frame can be limited on a working station, a sterilizing cylinder body is movably supported on the machine frame, a filter hole is formed in the side wall of the sterilizing cylinder body, a spiral guide groove capable of guiding materials to enter and exit the sterilizing cylinder body is formed in the inner wall of the sterilizing cylinder body, a material port used for feeding and discharging is formed in one end of the sterilizing cylinder body, and the specific connection structure between the machine frame and the sterilizing cylinder body is as follows: a supporting seat is arranged at one end of the frame, and two supporting wheels are respectively arranged at two sides of the bottom of the other end of the frame; a rotary shaft is arranged on the bottom of the other end of the sterilizing cylinder, the rotary shaft on the sterilizing cylinder is connected with the supporting seat in a matched manner and can rotate on the supporting seat, the sterilizing cylinder is placed on the two supporting wheels, and the two supporting wheels can be driven to rotate together when the sterilizing cylinder rotates; a sealing door is arranged on the shell positioned on the same side of the material opening, a discharging cavity is arranged on the inner wall of the sealing door, when the sealing door is closed with the shell and the frame is positioned on a working station, the material opening on the sterilizing cylinder body just stretches into the discharging cavity on the sealing door, a discharging pipe is arranged at the bottom of the discharging cavity, and extends outwards after penetrating through the sealing door downwards, and a butterfly valve is arranged on the discharging pipe extending out of the sealing door; a driving component is arranged between the shell and the sterilizing cylinder, the driving component can drive the sterilizing cylinder to rotate around the central axis of the sterilizing cylinder on the frame, when the sterilizing cylinder rotates positively, materials can gradually move into the sterilizing cylinder from the material port along the spiral material guide groove, and when the sterilizing cylinder rotates reversely, the materials in the sterilizing cylinder can gradually move towards the material port along the spiral material guide groove; a water delivery pipe is fixedly arranged on the frame, a high Wen Penlin pipe is connected to the water delivery pipe, a through hole is formed in a rotating shaft of the sterilization cylinder, a sealing bearing is arranged in the through hole, and the high Wen Penlin pipe penetrates through the sealing bearing and then stretches into an inner cavity of the sterilization cylinder; the drive assembly includes: the sterilization device comprises a shell, a sterilization cylinder, a servo motor, a transmission gear and a gear ring, wherein the servo motor is fixedly arranged in the shell, the transmission gear is fixedly connected to an output shaft of the servo motor, the gear ring is fixedly sleeved on the sterilization cylinder, the transmission gear is meshed with the gear ring, the servo motor drives the transmission gear to rotate, and the gear ring drives the sterilization cylinder to rotate on the frame under the action of gear transmission; the specific structure of the limiting device is as follows: a first stop block and a second stop block are respectively arranged on two sides of the front end and the rear end of the groove-shaped guide rail, wherein the first stop block is positioned on one side close to the material opening, the second stop block is positioned on one side close to the barrel bottom, a first stop block and a second stop block which can be respectively matched with the first stop block and the second stop block are arranged on the frame, the second stop block is fixedly arranged at the bottom of the frame, the rear end of the first stop block is hinged on a mounting plate fixed at the bottom of the frame, a limiting pin is arranged at the front end of the first stop block, a vertically long-strip-shaped hole is arranged at the front end of the mounting plate, the limiting pin is movably arranged in the long-strip-shaped hole in a penetrating manner, and when the front end of the first stop block rotates up and down around a hinge point of the limiting pin, the limiting pin moves up and down in the long-strip-shaped hole; when the frame pushes into the shell, the first limiting block is contacted with the first stop block, the front end of the first limiting block rotates upwards around the hinge point of the first limiting block under the pushing action of the first stop block, so that the first limiting block can clear the first stop block, when the frame reaches a working station, the second limiting block can lean against the front end of the second stop block, and after the front end of the first limiting block passes over the first stop block, the front end of the first limiting block falls under the action of dead weight and carries with the limiting pin, so that the front end of the first limiting block just leans against the rear end of the first stop block, and at the moment, the limiting pin falls at the bottom of the long-strip-shaped hole, so that the frame is limited on the working station; when the frame is required to be pulled out, the frame can be pulled out after the first limiting block is lifted upwards to be higher than the first stop block.

2. A rotary dynamic sterilization cabinet for cleaning rubber plugs according to claim 1, wherein: the concrete connection structure between the supporting wheel and the frame is: the two sides of the frame are respectively fixedly provided with a T-shaped groove track, each T-shaped groove track is movably provided with a supporting wheel frame, each supporting wheel frame can move in the corresponding T-shaped groove track, two supporting wheels are respectively hinged on the two supporting wheel frames, each T-shaped groove track is respectively transversely provided with a thick plate, each thick plate is provided with two threaded through holes, the two threaded through holes on each thick plate are aligned with the supporting wheel frames in the corresponding T-shaped groove tracks, each threaded through hole is in threaded connection with a screw rod, the top ends of the screw rods penetrate through the thick plates connected with each other and then are propped against the supporting wheel frames, and each screw rod is respectively provided with a locking nut.

3. A rotary dynamic sterilization cabinet for cleaning rubber plugs according to claim 2, wherein: the two supporting wheels are provided with annular grooves, the outer side of the sterilizing cylinder body is provided with annular wheels protruding out of the sterilizing cylinder body, and the annular wheels extend into the annular grooves on the two supporting wheels.

4. A rotary dynamic sterilization cabinet for cleaning rubber plugs according to claim 1, wherein: the concrete connection structure of supporting seat and frame is: a trapezoid support is fixedly arranged on the frame, and two through holes are formed in a cross bar at the upper part of the trapezoid support; the bottom of the supporting seat is provided with two threaded holes, the supporting seat is sleeved on the cross rod of the trapezoid bracket, the two threaded holes on the supporting seat are aligned with the two through holes on the cross rod respectively, and the two bolts respectively penetrate through the two through holes on the cross rod and then are screwed with the two threaded holes on the supporting seat to be fixed, so that the supporting seat is fixed on the trapezoid bracket.

5. A rotary dynamic sterilization cabinet for cleaning rubber plugs as defined in claim 4, wherein: a connecting rod is arranged between waist bars on two sides of the trapezoid support, a connecting plate is fixedly arranged on the connecting rod, an arc-shaped groove capable of clamping a water supply pipe is arranged at the outer end of the connecting plate, and an arc-shaped pipe clamping ring is fixedly arranged on the arc-shaped groove after the water supply pipe is clamped in the arc-shaped groove, so that the water supply pipe is fixed on the connecting plate.

6. A rotary dynamic sterilization cabinet for cleaning rubber plugs according to claim 1, wherein: the concrete connection structure between the supporting seat and the sterilizing cylinder body is as follows: the sterilizing device comprises a sterilizing cylinder body, a supporting seat, a rotating shaft, a connecting hole, a limiting screw, a rotating shaft and a limiting screw, wherein the connecting hole is formed in the supporting seat, two bearings are fixedly arranged in the connecting hole, the rotating shaft on the sterilizing cylinder body is arranged in the two bearings in a penetrating mode and extends out of the supporting seat, two threaded holes are formed in the rotating shaft extending out of the supporting seat, the limiting screw protruding outwards from the rotating shaft is respectively connected in the two threaded holes, and the rotating shaft can be prevented from being separated from the bearings.

7. A rotary dynamic sterilization cabinet for cleaning rubber plugs according to claim 1, wherein: a sewage draining groove is arranged in the shell below the sterilizing cylinder.