CN117516074A - Vertical rotary multi-station centrifugal spin-drying equipment - Google Patents

Abstract

The invention discloses vertical rotary multi-station centrifugal drying equipment, which comprises a drying mechanism, a material conveying mechanism and a material feeding mechanism, wherein the drying mechanism comprises a fixed barrel and a drying barrel; the conveying mechanism comprises two mounting frames, a plurality of bearing plates positioned between the two mounting frames and a driving motor which is arranged on the side wall of one of the mounting frames and drives the plurality of bearing plates to reciprocate along the extending direction of the mounting frame during working; the feeding mechanism is used for automatically driving the feeding mechanism to start working when the driving motor works to drive the plurality of bearing plates to move along the extending direction of the mounting frame, the plastic basket on the surface of the bearing plates is guided into the fixing groove inside the spin-drying barrel, and the feeding mechanism works to drive the spin-drying barrel to intermittently stop rotating, so that the problem that the plastic basket is required to be fed through a large-size robot arm when being spin-dried is solved, the use cost is high, the shutdown operation is required during feeding, the time is wasted, and the production cost of enterprises is improved.

Description

Vertical rotary multi-station centrifugal spin-drying equipment

Technical Field

The invention relates to the technical field of spin-drying devices, in particular to vertical rotary multi-station centrifugal spin-drying equipment.

Background

Plastic products are applied in a plurality of fields, the plastic basket needs to be disinfected after being produced, and because the disinfectant is remained on the single basket, the disinfectant remained on the surface of the plastic basket needs to be cleaned before the plastic basket is assembled in a factory, and at present, the most direct cleaning mode mainly comprises the steps of rotating a centrifugal machine to drive the plastic basket to rotate at high height and then spin-drying the disinfectant on the surface of the plastic basket by utilizing centrifugal force.

The device that current disinfection water on the plastic basket spin-dries mainly is near carrying the plastic basket spin-dry barrel through the conveying mechanism, then inserts the fixed slot of spin-dry barrel after being held it by robotic arm and carries out the material loading, but this kind of mode robotic arm's working radius is great, gets into and needs jumbo size robotic arm to transport the plastic basket, and then causes equipment use cost higher, and need shut down the processing in-process of material loading, has wasted a large amount of time to the manufacturing cost of messenger enterprise is higher.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the invention, which should not be used to limit the scope of the invention.

Therefore, the invention aims to provide the vertical rotary multi-station centrifugal spin-drying equipment, which replaces the traditional feeding mode when the sterilizing water on the plastic basket is spin-dried, and avoids the problems that the use cost is high, the shutdown operation is needed during feeding, the time is wasted and the production cost of enterprises is increased because the feeding is needed through a large-size robot arm when the plastic basket is spin-dried.

In order to solve the technical problems, according to one aspect of the present invention, the following technical solutions are provided:

a vertical rotary multi-station spin-drying apparatus, comprising:

the spin-drying mechanism comprises a fixed barrel with an opening structure at the top, and a plurality of spin-drying barrels which are positioned in the fixed barrel and uniformly provided with a plurality of fixed grooves along the circumferential direction of the inner wall of the spin-drying barrel;

the conveying mechanism comprises two obliquely upward mounting frames, a plurality of bearing plates which are positioned between the two mounting frames and are used for bearing a plastic basket, and a driving motor which is arranged on the side wall of one mounting frame and drives the plurality of bearing plates to reciprocate along the extending direction of the mounting frame during working;

and one end of the feeding mechanism is in transmission connection with the material conveying mechanism, the other end of the feeding mechanism corresponds to the fixing groove in the spin-drying barrel, when the driving motor works to drive the bearing plates to move along the extending direction of the mounting frame, the feeding mechanism is automatically driven to start working, the plastic basket on the surface of the bearing plate is led into the fixing groove in the spin-drying barrel, and when the feeding mechanism works, the spin-drying barrel is automatically driven to intermittently stop rotating, so that the next fixing groove corresponds to one end, far away from the material conveying mechanism, of the feeding mechanism.

As a preferable scheme of the vertical rotary multi-station centrifugal spin-drying device, the fixed barrel comprises an outer barrel body positioned outside the spin-drying barrel and a supporting base positioned at the bottom of the outer barrel body and provided with a rotary motor, and the output end of the rotary motor is connected with the bottom of the spin-drying barrel.

As a preferable scheme of the vertical rotary multi-station centrifugal drying equipment, the inner wall of the drying barrel is uniformly provided with a plurality of partition boards with holes on the side wall along the circumferential direction, and two adjacent partition boards form the fixed groove.

As a preferable scheme of the vertical rotary multi-station centrifugal drying equipment, the outer side wall and the bottom of the drying barrel are provided with hydrophobic holes;

the bottom of the supporting base is provided with a drain pipe communicated with the bottom of the inner wall of the outer barrel body.

As a preferable scheme of the vertical rotary multi-station centrifugal spin-drying device, the top and the bottom of the spin-drying barrel are provided with connecting rings which are attached to the inner wall of the outer barrel body and have an outer diameter larger than the outer diameter of the spin-drying barrel.

As a preferable scheme of the vertical rotary multi-station centrifugal drying equipment, the mounting frame comprises a shell with a support frame on the side wall and crawler wheels on the two ends inside and a shell cover positioned at the opening of the side wall of the shell, a transmission crawler is connected between the two crawler wheels, the side wall of one crawler wheel of the mounting frame is connected with the output end of the driving motor through a rotating shaft, and an annular limiting chute which is consistent with the extending direction of the shell and forms a closed loop is formed on the side wall of the shell cover;

the two sides of the bearing plate are provided with connecting rods which extend into the annular limiting sliding grooves and are movably connected with the side walls of the conveying crawler belt.

As a preferable scheme of the vertical rotary multi-station centrifugal spin-drying equipment, the feeding mechanism comprises a discharge assembly which is arranged at the top of the supporting frame and moves a plastic basket close to the top of the bearing plate of the spin-drying barrel out of the top of the bearing plate when in operation, and a guide assembly which is arranged at the top of the outer barrel body and has two ends corresponding to the output end of the discharge assembly and a plurality of fixing grooves respectively.

As a preferable scheme of the vertical rotary multi-station centrifugal drying equipment, the side wall of one of the crawler wheels far away from the inner wall of the shell of the driving motor is connected with a first belt pulley through a rotating shaft;

the material discharging assembly comprises a fixing frame positioned at the top of the supporting frame, a material discharging roller positioned between the two fixing frames and provided with a material stirring plate on the surface, and a transmission assembly which is in transmission connection with the material discharging roller and drives the material guiding assembly to work when the material discharging roller rotates, wherein one side of the material discharging roller is connected with a second belt pulley connected with the first belt pulley through a belt through a rotating shaft.

As a preferable scheme of the vertical rotary multi-station centrifugal drying equipment, a half-tooth gear is arranged at one end of the discharging roller, which is far away from the second belt pulley, and a full-tooth gear meshed with the half-tooth gear is arranged on the side wall of the fixing frame;

the transmission assembly comprises a first bevel gear set, one end of which is connected with the side wall of the full-tooth gear, and a third belt pulley, and the third belt pulley is connected with the other end of the first bevel gear set.

As a preferable scheme of the vertical rotary multi-station centrifugal drying equipment, the top of the outer barrel body is provided with a clamping groove, the top of the outer barrel body is provided with a mounting plate, and the bottom of the mounting plate is connected with a limiting cylinder with a limiting groove on the inner wall through a connecting frame;

an elastic pawl is arranged at the output end of the rotating motor, and a pawl groove matched with the elastic pawl is formed in the bottom of the spin dryer tube;

the top of the inner wall of the spin dryer tube is provided with a connecting shaft, the top of the connecting shaft is provided with a limiting column matched with the limiting tube, and the top of the limiting column is provided with a reciprocating screw rod;

the guide assembly comprises a fixed basket which is clamped in the clamping groove and is close to the bearing plate, wherein one side of the fixed basket is of an opening structure, and a guide frame which is rotationally connected to the inner wall of the fixed basket and is of an opening structure at two ends of the fixed basket, one end, far away from the bearing plate, of the guide frame is connected with a fourth belt pulley connected with the third belt pulley through a belt through a rotating shaft, the side wall of the fourth belt pulley is connected with a second bevel gear set which is installed at the bottom of the mounting plate, the other end of the second bevel gear set is provided with a threaded cylinder, and the threaded cylinder is matched with the reciprocating screw rod.

Compared with the prior art, the vertical type rotary multi-station centrifugal spin-drying device has the advantages that the spin-drying barrel rotates at a high speed to drive the internal plastic basket to carry out centrifugal spin-drying operation, the plastic basket to be spin-dried is conveyed to the position close to the spin-drying barrel through the bearing plate by the material conveying mechanism, meanwhile, the material conveying mechanism is driven to start working to discharge the plastic basket on the surface of the bearing plate into the fixed groove in the spin-drying barrel, meanwhile, the material conveying mechanism is operated to automatically drive the spin-drying barrel to intermittently stop rotating, so that the next fixed groove is conveniently fed, the next fixed groove is conveniently rotated to the feeding position, a robot arm is not required to feed, and the centrifugal operation is not delayed while feeding is carried out, so that the traditional mode of feeding sterilizing water on the plastic basket during spin-drying is replaced, the problem that the plastic basket is required to be fed through a large-size robot arm during spin-drying is avoided, the use cost is high, the feeding is required, the operation is stopped while the feeding is required, and the production cost is increased.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following detailed description of the embodiments of the present invention will be given with reference to the accompanying drawings, which are to be understood as merely some embodiments of the present invention, and from which other drawings can be obtained by those skilled in the art without inventive faculty. Wherein:

FIG. 1 is a schematic view of a perspective view of a vertical rotary multi-station spin-dryer apparatus of the present invention;

FIG. 2 is a schematic view of another view angle of a vertical rotary multi-station spin-drying apparatus according to the present invention;

FIG. 3 is a structural exploded view of a vertical rotary multi-station spin-drying apparatus according to the present invention;

fig. 4 is a schematic structural view of a spin dryer tube of a vertical rotary multi-station centrifugal spin dryer apparatus according to the present invention;

FIG. 5 is a split view of a connection structure between two mounting frames and a carrier plate of a vertical rotary multi-station centrifugal drying apparatus according to the present invention;

FIG. 6 is a structural exploded view of a mounting frame of a vertical spin-on multi-station spin-dryer apparatus according to the present invention;

FIG. 7 is a schematic view of a discharge roller of a vertical rotary multi-station spin-drying apparatus according to the present invention;

fig. 8 is a schematic structural view of a guide assembly of a vertical rotary multi-station centrifugal drying apparatus according to the present invention.

In the figure: 100. a spin-drying mechanism; 110. a fixed barrel; 110a, an outer tub; 110a-1, a clamping groove; 110a-2, a mounting plate; 110a-21, a limiting cylinder; 110a-211, a limit groove; 110b, a support base; 110b-1, a rotating electrical machine; 110b-2, a drain pipe; 120. spin dryer tube; 120a, a separator; 120b, hydrophobic pores; 120c, a connecting shaft; 120c-1, a limit column; 120c-2, a reciprocating screw rod; 120d, a connecting ring; 200. a material conveying mechanism; 210. a mounting frame; 210a, a housing; 210a-1, a support frame; 210a-2, track wheel; 210a-21, a conveyor track; 210a-22, a first pulley; 210b, a shell cover; 210b-1, annular limiting chute; 220. a carrying plate; 220a, connecting rods; 230. a driving motor; 300. a feeding mechanism; 310. a discharge assembly; 310a, a fixing frame; 310b, a discharge roller; 310b-1, a second pulley; 310b-2, half-tooth gears; 310b-21, full tooth gear; 310c, a transmission assembly; 310c-1, a first bevel gear set; 310c-2, a third pulley; 320. a material guiding component; 320a, fixing a basket; 320b, a material guide frame; 320b-1, a fourth pulley; 320b-2, a second bevel gear set; 320b-21, a threaded cylinder.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to the appended drawings.

Next, the present invention will be described in detail with reference to the drawings, wherein the sectional view of the device structure is not partially enlarged to general scale for the convenience of description, and the drawings are only examples, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.

The invention provides vertical rotary multi-station centrifugal spin-drying equipment, which replaces the traditional feeding mode when sterilizing water on a plastic basket is spin-dried, and solves the problems that the use cost is high, the shutdown operation is required during feeding, the time is wasted and the production cost of enterprises is increased because the feeding is required through a large-size robot arm when the plastic basket is spin-dried.

Fig. 1 to 8 are schematic structural views of a vertical rotary multi-station centrifugal drying apparatus according to the present invention, and fig. 1 to 8 are detailed descriptions of the vertical rotary multi-station centrifugal drying apparatus.

Example 1

Referring to fig. 1 to 8, the present invention discloses a vertical rotary multi-station centrifugal drying apparatus, the main body of which includes a drying mechanism 100, a feeding mechanism 200, and a feeding mechanism 300.

Referring to fig. 1 to 3, a spin-drying mechanism 100 is used for spin-drying sterilizing water entering the outer surface of an internal plastic basket, the spin-drying mechanism 100 comprises a fixed barrel 110 with an opening structure at the top and a spin-drying barrel 120 which is positioned in the fixed barrel 110 and uniformly provided with a plurality of fixed grooves along the circumferential direction of the inner wall of the fixed barrel, the fixed barrel 110 is used for bearing the spin-drying barrel 120, so as to maintain the stability of the spin-drying barrel 120 during rotation, the spin-drying barrel 120 is used for driving the internal plastic basket to rotate at a high speed during rotation, so as to spin-dry the sterilizing water on the surface of the plastic basket, and the fixed grooves are used for separating and fixing the plastic baskets, so as to provide spin-drying stations of the plastic baskets.

Referring to fig. 1 to 3, the feeding mechanism 200 is used for feeding a plastic basket to be dried, which is transferred through the transferring mechanism, to a position of the top of the drying tub 120 adjacent to the drying tub 120, the feeding mechanism 200 includes two obliquely upward mounting frames 210, a plurality of carrying plates 220 positioned between the two mounting frames 210 and used for carrying the plastic basket, and a driving motor 230 installed on a sidewall of one of the mounting frames 210 and driving the plurality of carrying plates 220 to reciprocate along an extending direction of the mounting frame 210 when working, the mounting frame 210 is used for facilitating installation of the plurality of carrying plates 220, the carrying plates 220 are used for carrying the plastic basket, and driving the plastic basket to move when moving, and the driving motor 230 is used for driving the plurality of carrying plates 220 to reciprocate along the extending direction of the mounting frame 210 when working, and continuously feeding the plurality of plastic baskets to the top of the drying tub 120.

Referring to fig. 1 to 3, the feeding mechanism 300 is used for automatically driving the feeding mechanism 300 to start to work when the feeding mechanism 200 works, the plastic basket which is transmitted to the top of the spin dryer tube 120 through the bearing plate 220 is led into the fixed slot inside the spin dryer tube 120, one end of the feeding mechanism 300 is in transmission connection with the feeding mechanism 200, and the other end of the feeding mechanism 300 corresponds to the fixed slot inside the spin dryer tube 120, the feeding mechanism 300 is used for conveniently leading the plastic basket on the bearing plate 220 into the fixed slot inside the spin dryer tube 120, wherein when the driving motor 230 works to drive the plurality of bearing plates 220 to move along the extending direction of the mounting frame 210, the feeding mechanism 300 is automatically driven to start to work, the plastic basket on the surface of the bearing plate 220 is led into the fixed slot inside the spin dryer tube 120, the feeding mechanism 300 is automatically driven to work through the feeding mechanism 200, a separate power source is not required to be additionally arranged, the use cost of equipment is reduced, and when the feeding mechanism 300 works, the spin dryer tube 120 is automatically driven to intermittently stop rotating, the next fixed slot and the corresponding one end of the feeding mechanism 300 is far from the fixed slot inside the spin dryer tube 120, the spin dryer tube is conveniently stopped, and the whole spin-drying process is conveniently completed after the spin-drying operation is completed, and the whole spin-drying process is completed.

In this embodiment, the specific usage flow is as follows: referring to fig. 1 to 3, when the spin-drying tub 120 rotates at a high speed, the inner plastic basket is driven to rotate at a high speed to separate the sterilization water on the surface of the spin-drying tub 120, when the driving motor 230 operates, the plurality of bearing plates 220 are driven to reciprocate along the extending direction of the mounting frame 210, and then the plastic basket transmitted by the transmission mechanism is continuously transmitted to the top of the spin-drying tub 120 through the plurality of bearing plates 220, meanwhile, the material conveying mechanism 200 operates to automatically drive the feeding mechanism 300 to start to operate so as to introduce the plastic basket adjacent to the top of the bearing plate 220 at the top of the spin-drying tub 120 into the fixing groove in the spin-drying tub 120, and then one-time feeding is completed, and meanwhile, the feeding mechanism 300 operates to automatically drive the spin-drying tub 120 to intermittently stop rotating, so that the next fixing groove is conveniently fed, and thus the continuous feeding of a large-size robot arm is not required, and the centrifugal operation is performed after the feeding of all the fixing grooves is completed, so that the use cost of the equipment is reduced and the whole working time is saved.

Example 2

On the basis of embodiment 1, referring to fig. 1-3, the fixed tub 110 includes an outer tub body 110a located outside the spin tub 120, and a support base 110b located at the bottom of the outer tub body 110a and having a rotating motor 110b-1 at the bottom, the outer tub body 110a is used for carrying the spin tub 120, the support base 110b is used for supporting the outer tub body 110a, and maintaining stability of the outer tub body 110a, thereby maintaining stability of the whole apparatus during operation, an output end of the rotating motor 110b-1 of the support base 110b is connected with the bottom of the spin tub 120, and the rotating motor 110b-1 is used for driving the spin tub 120 to rotate at a high speed during operation, thereby driving the plastic basket in the inner fixed tub to rotate at a high speed, so that sterilizing water on the outer surface of the plastic basket is separated from the outer surface of the plastic basket under centrifugal force.

In this embodiment, referring to fig. 1 to 4, the inner wall of the spin-drying tub 120 is uniformly provided with a plurality of partitions 120a having holes on the sidewalls along the circumferential direction, the partitions 120a are used to form a fixing groove, so that a centrifugal operation is facilitated to carry a plurality of plastic baskets, the holes on the sidewalls of the partitions 120a are used to facilitate the sterilization water on the outer surface of the plastic basket to be thrown out through the holes under the centrifugal force, and two adjacent partitions 120a form the fixing groove to fix the plastic basket spin-dried by large centrifugation, so as to avoid the influence of the mutual lamination of the plastic baskets on the separation of the sterilization water during the centrifugal operation, and further reduce the spin-drying effect.

In this embodiment, referring to fig. 3 to 4, the outer sidewall and the bottom of the spin-drying tub 120 are provided with a drain hole 120b for facilitating the thrown sterilizing water to enter the bottom of the inner wall of the outer tub 110a through the drain hole 120 b;

referring to fig. 1 to 3, a drain pipe 110b-2 communicating with the bottom of the inner wall of the outer tub 110a is provided at the bottom of the support base 110b for discharging the sterilized water thrown out inside the outer tub 110a, thereby achieving dry-wet separation.

In this embodiment, referring to fig. 1-6, the mounting rack 210 includes a housing 210a with a supporting frame 210a-1 on a side wall and with crawler wheels 210a-2 at two ends inside, and a housing cover 210b located at an opening of the side wall of the housing 210a, where the housing 210a is used to facilitate installation of the crawler wheels 210a-2, the crawler wheels 210a-2 are used to drive the crawler wheels 210a-21 to move when rotating, the housing cover 210b is used to block one side of the opening of the housing 210a, and facilitate installation connection of the other side of the crawler wheels 210a-2, a conveying crawler 210a-21 is connected between the two crawler wheels 210a-2, and is used to drive the carrier plate 220 to move when moving, wherein the side wall of one crawler wheel 210a-2 of the mounting rack 210 is connected with an output end of the driving motor 230 through a rotating shaft, and is used to drive the crawler wheels 210a-2 to rotate when the driving motor 230 is working, and then drive the conveying crawler wheels 210a-21 to move, and the side wall of the housing cover 210b is provided with an annular limiting chute 210b-1 which is consistent with the extending direction of the housing 210a and forms a closed loop, and is used to drive the carrier plate 220 to move when the conveying 210a-21 to move, and the carrier plate 220 is made to move along the annular limiting chute 220 and the carrier plate 220 to move along the carrier plate 220 and further to prevent the carrier plate from sliding along the carrier plate 220 from moving along the horizontal plane in the top plane;

referring to fig. 1 to 6, connecting rods 220a extending into the annular limiting sliding groove 210b-1 and movably connected with the side walls of the conveying tracks 210a-21 are disposed at two sides of the bearing plate 220, and are used for respectively extending into the annular limiting sliding groove 210b-1 and then connecting with the side walls of the two conveying tracks 210a-21, so that when the conveying tracks 210a-21 move, the bearing plates 220 are driven to move reciprocally along the annular limiting sliding groove 210b-1, and further, plastic baskets to be centrifuged, which are conveyed by the conveying mechanism, are continuously conveyed to the feeding mechanism 300 for feeding.

In this embodiment, referring to fig. 1 to 8, the feeding mechanism 300 includes a discharging assembly 310 installed at the top of the supporting frame 210a-1 and operative to move the plastic basket adjacent to the top of the loading plate 220 of the spin-drying tub 120 out of the top of the loading plate 220, and a guiding assembly 320 installed at the top of the outer tub 110a and having two ends corresponding to the output end of the discharging assembly 310 and a plurality of fixing slots, respectively, wherein the discharging assembly 310 is configured to automatically drive the feeding mechanism 200 to operate when the feeding mechanism operates, so that the plastic basket adjacent to the top of the loading plate 220 of the spin-drying tub 120 is moved out of the top of the loading plate 220, thereby completing the separation of the plastic basket from the loading plate 220, and the guiding assembly 320 is configured to guide the plastic basket moved out of the loading plate 220 through the discharging assembly 310 into the fixing slots inside the spin-drying tub 120, thereby completing the feeding when the feeding mechanism 200 delivers the plastic basket to the top of the spin-drying tub 120, without a robotic arm.

In this embodiment, referring to fig. 1-6, a first pulley 210a-22 is connected to a side wall of one of the track wheels 210a-2 far away from the inner wall of the housing 210a of the driving motor 230 through a rotating shaft, and is used to drive the plurality of track wheels 210a-2 to synchronously rotate under the connection action of the transmission track 210a-21 when the driving motor 230 works to drive one of the track wheels 210a-2 to rotate, so as to drive the first pulley 210a-22 to rotate, and the first pulley 210a-22 is used to drive the second pulley 310b-1 to rotate when rotating;

referring to fig. 1-8, the discharging assembly 310 includes a fixing frame 310a located at the top of the supporting frame 210a-1, a discharging roller 310b located between the two fixing frames 310a and having a deflector on the surface thereof, and a transmission assembly 310c in transmission connection with the discharging roller 310b and driving the guiding assembly 320 to operate when the discharging roller 310b rotates, wherein the fixing frame 310a is used for conveniently installing the discharging roller 310b, the discharging roller 310b is used for driving the deflector to rotate when rotating, the rotating deflector is used for pulling out the plastic basket on the top surface of the carrier 220 from the top of the carrier 220, and further separating the plastic basket from the carrier 220 is completed, one side of the discharging roller 310b is connected with a second pulley 310b-1 connected with the first pulley 210a-22 through a belt through a rotating shaft, and is used for driving the discharging roller 310b to rotate when the driving motor 230 drives the second pulley 310b-1 to rotate after driving the first pulley 210a-22 to rotate, and driving the discharging roller 310b to rotate when the second pulley 310b-1 rotates, and further driving the plastic basket on the top surface of the carrier 220 from the carrier 220.

In this embodiment, one end of the discharging roller 310b far away from the second pulley 310b-1 is provided with a half-tooth gear 310b-2, which is used for intermittently driving the full-tooth gear 310b-21 to intermittently rotate when the discharging roller 310b rotates to drive the discharging roller to rotate, the side wall of the fixing frame 310a is provided with the full-tooth gear 310b-21 meshed with the half-tooth gear 310b-2, which is used for driving the transmission component 310c to work when rotating, and the saw tooth number of the half-tooth gear 310b-2 is one fourth of the saw tooth number of the full-tooth gear 310b-21, which is used for conveniently driving the material guiding frame 320b to intermittently rotate by ninety degrees, so that the plastic basket inside the material guiding frame 320c is conveniently slid into the fixing groove;

the transmission assembly 310c includes a first bevel gear set 310c-1 having one end connected to a sidewall of the full-tooth gear 310b-21 and a third pulley 310c-2 connected to the other end of the first bevel gear set 310c-1, the first bevel gear set 310c-1 for driving the third pulley 310c-2 to rotate when the full-tooth gear 310b-21 rotates and the third pulley 310c-2 for driving the fourth pulley 320b-1 to rotate when rotating.

In this embodiment, referring to fig. 1-7, a clamping groove 110a-1 is formed at the top of the outer barrel 110a, for facilitating the clamping of the fixing basket 320a, a mounting plate 110a-2 is arranged at the top of the outer barrel 110a, for facilitating the mounting of the limiting cylinder 110a-21, so as to maintain stability thereof, the bottom of the mounting plate 110a-2 is connected with a limiting cylinder 110a-21 having a limiting groove 110a-211 in the inner wall thereof through a connecting frame, for adapting to the limiting column 120c-1, so as to drive the connecting shaft 120c and the reciprocating screw 120c-2 to move up and down under the limiting action of the limiting cylinder 110a-21 and the limiting column 120c-1 when the screw cylinder 320b-21 rotates;

the output end of the rotary motor 110b-1 is provided with an elastic pawl, the bottom of the spin-drying barrel 120 is provided with a pawl groove matched with the elastic pawl, and the pawl groove is used for facilitating repeated connection and disconnection between the spin-drying barrel 120 and the output end of the motor when the connecting shaft 120c moves up and down to drive the spin-drying barrel 120 to move up and down, so that the spin-drying barrel 120 stops rotating intermittently, and feeding of the next fixed groove is facilitated;

referring to fig. 1 to 7, a connection shaft 120c is provided at the top of the inner wall of the spin-drying tub 120, for driving the spin-drying tub 120 to move up and down when moving up and down, a limit post 120c-1 adapted to the limit tub 110a-21 is provided at the top of the connection shaft 120c, for conveniently driving the reciprocating screw 120c-2 to drive the spin-drying tub 120 to move up and down when the screw 320b-21 rotates, preventing the reciprocating screw from synchronously rotating along with the screw 320b-21, and the limit post 120c-1 is provided at the top with the reciprocating screw 120c-2, for driving the screw 320b-21 to move in the screw 320b-21 when rotating, thereby driving the spin-drying tub 120 to reciprocate up and down, and further driving the spin-drying tub 120 to intermittently separate from the output end of the motor, facilitating feeding in the centrifuging process, and simultaneously, a drain hole 120b at the bottom is separated from the bottom of the inner wall of the outer tub 110a, thereby indirectly realizing one-time drainage of the spin-drying tub 120 once when stopping the feeding once;

referring to fig. 1-8, the material guiding assembly 320 includes a fixing basket 320a which is clamped in the clamping groove 110a-1 and is adjacent to the loading plate 220, and a material guiding frame 320b which is rotatably connected to the inner wall of the fixing basket 320a and is provided with an opening structure at both ends, wherein the fixing basket 320a is used for conveniently installing the material guiding frame 320b, the material guiding frame 320b is used for loading a plastic basket which is pulled down by the material discharging roller 310b, one end of the material guiding frame 320b, which is far away from the loading plate 220, is connected with a fourth belt pulley 320b-1 which is connected with a third belt pulley 310c-2 through a belt through a rotating shaft, the fourth belt pulley 320b-1 is used for driving the fourth belt pulley 320b-1 to rotate by the third belt pulley 310c-2, and further driving the material guiding frame 320b to intermittently rotate by ninety degrees when the fourth belt pulley 320b-1 rotates, so as to conveniently discharge the internal plastic basket into the fixing groove, the side wall of the fourth belt pulley 320b-1 is connected with a second bevel gear set 320b-2 which is installed at the bottom of the mounting plate 110a-2 and is provided with a threaded drum 320b-21, when the fourth belt pulley 320b-1 is used for driving the second bevel drum 320b-21 to rotate, and the second bevel drum 320b-21 is driven by the second bevel drum 320b-21 to rotate, and the bevel drum 320b-21 is driven to rotate by the screw, and then the screw 120-2-rotates reciprocally when the second bevel drum 320b-21 b is driven by the bevel drum rotates.

In this embodiment, the specific usage flow is as follows: referring to fig. 1 to 8, the plastic basket transferred to the carrier 220 through the transfer mechanism is sequentially transferred to the top position of the spin basket 120 by the transfer mechanism 200, the discharge mechanism is driven to work while the transfer mechanism 200 works, the driving motor 230 drives the crawler wheel 210a-2 to rotate and further drives the first belt pulley 210a-22 to rotate, the first belt pulley 210a-22 drives the second belt pulley 310b-1 to rotate under the connection action of the belt and further drives the discharge roller 310b to rotate, the plastic basket on the carrier 220 is pulled out of the carrier 220 and then enters the guide frame 320b when the discharge roller 310b rotates, the guide frame 320b is driven to intermittently rotate ninety degrees under the connection action of the transmission component 310c in the process, the plastic basket inside the guide frame 320b is discharged into the fixed groove, the first belt pulley 210a-22 rotates and then drives the spin basket 120 to reciprocate up and down under the connection action of the belt, the discharge roller 310b rotates and then drives the output end of the rotary motor 110b-1 to rotate, the centrifugal basket 120 is driven to rotate and then enters the guide frame 320b, the centrifugal basket is driven to intermittently rotate at ninety degrees under the connection action of the transmission component 310c in the process, the process is unnecessary, the continuous material-down time is reduced, and the manual material-stop time is avoided, and the continuous material-feeding operation is carried out by a continuous process in the process, and the process is realized, and the manual material-down time is realized, and the continuous down time is realized, and the production time is convenient, and the production time is continuous, and the production time is convenient.

Example 3

On the basis of embodiment 2, in order to prevent the sterilizing water led out through the hydrophobic hole 120b of the side wall of the spin-drying tub 120 from being blocked by the inner wall of the outer tub 110a and causing the water to be discharged slowly, referring to fig. 1 to 4, the top and bottom of the spin-drying tub 120 are provided with connection rings 120d attached to the inner wall of the outer tub 110a and having an outer diameter larger than the outer diameter of the spin-drying tub 120, so as to isolate a water discharge space between the outer side wall of the spin-drying tub 120 and the inner wall of the outer tub 110a, thereby facilitating the separated sterilizing water in the spin-drying tub 120 to drop to the bottom of the inner wall of the outer tub 110a after entering the inside of the outer tub 110a through the hydrophobic hole 120 b.

In this embodiment, the specific usage flow is as follows: when the rotary motor 110b-1 operates to drive the spin-drying tub 120 to rotate at a high speed, the plurality of plastic baskets in the fixing groove inside the spin-drying tub 120 rotate at a high speed in synchronization, so that the sterilizing water on the outer surface of the plastic basket is separated from the outer surface of the plastic basket under the action of centrifugal force, and the separated sterilizing water enters into the space between the inner wall of the outer tub 110a and the outer side wall of the spin-drying tub 120 through the hydrophobic hole 120b on the side wall of the spin-drying tub 120 under the action of centrifugal force, so that the sterilizing water is conveniently discharged through the drain pipe 110b-2 after flowing into the bottom of the inner wall of the outer tub 110 a.

Although the invention has been described hereinabove with reference to embodiments, various modifications thereof may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the features of the disclosed embodiments may be combined with each other in any manner as long as there is no structural conflict, and the exhaustive description of these combinations is not given in this specification merely for the sake of omitting the descriptions and saving resources. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (10)

1. A vertical rotary multi-station spin-drying apparatus, comprising:

the spin-drying mechanism (100) comprises a fixed barrel (110) with an opening structure at the top and a spin-drying barrel (120) which is positioned in the fixed barrel (110) and is uniformly provided with a plurality of fixed grooves along the circumferential direction of the inner wall of the spin-drying mechanism;

the conveying mechanism (200) comprises two obliquely upward mounting frames (210), a plurality of bearing plates (220) which are positioned between the two mounting frames (210) and are used for bearing a plastic basket, and a driving motor (230) which is arranged on the side wall of one mounting frame (210) and is used for driving the plurality of bearing plates (220) to reciprocate along the extending direction of the mounting frame (210) when in operation;

and one end of the feeding mechanism (300) is in transmission connection with the feeding mechanism (200), the other end of the feeding mechanism is corresponding to the fixing groove in the spin dryer tube (120), when the driving motor (230) works to drive the plurality of bearing plates (220) to move along the extending direction of the mounting frame (210), the feeding mechanism (300) is automatically driven to start working, a plastic basket on the surface of the bearing plates (220) is led into the fixing groove in the spin dryer tube (120), and when the feeding mechanism (300) works, the spin dryer tube (120) is automatically driven to intermittently stop rotating, so that the next fixing groove corresponds to one end, away from the feed mechanism (200), of the feeding mechanism (300).

2. The vertical rotary multi-station centrifugal drying apparatus according to claim 1, wherein the fixed tub (110) comprises an outer tub body (110 a) located outside the drying tub (120) and a support base (110 b) located at the bottom of the outer tub body (110 a) and having a rotary motor (110 b-1) at the bottom, and an output end of the rotary motor (110 b-1) is connected to the bottom of the drying tub (120).

3. The vertical rotary multi-station centrifugal drying apparatus according to claim 2, wherein a plurality of partitions (120 a) having holes on side walls are uniformly provided on an inner wall of the drying tub (120) along a circumferential direction, and two adjacent partitions (120 a) form the fixing groove.

4. The vertical rotary multi-station centrifugal drying apparatus according to claim 2, wherein the outer side wall and bottom of the drying tub (120) are provided with water drain holes (120 b);

the bottom of the supporting base (110 b) is provided with a drain pipe (110 b-2) communicated with the bottom of the inner wall of the outer barrel body (110 a).

5. The vertical rotary multi-station centrifugal spin-drying device according to claim 2, wherein the top and bottom of the spin-drying tub (120) are provided with connection rings (120 d) which are attached to the inner wall of the outer tub body (110 a) and have an outer diameter larger than the outer diameter of the spin-drying tub (120).

6. The vertical rotary multi-station centrifugal drying device according to claim 5, wherein the mounting frame (210) comprises a shell (210 a) with a supporting frame (210 a-1) on the side wall and crawler wheels (210 a-2) on the two ends inside, and a shell cover (210 b) positioned at the opening of the side wall of the shell (210 a), a conveying crawler belt (210 a-21) is connected between the two crawler wheels (210 a-2), the side wall of the crawler wheel (210 a-2) of one mounting frame (210) is connected with the output end of the driving motor (230) through a rotating shaft, and an annular limiting chute (210 b-1) which is consistent with the extending direction of the shell (210 a) and forms a closed loop is formed on the side wall of the shell cover (210 b);

connecting rods (220 a) extending into the annular limiting sliding grooves (210 b-1) and movably connected with the side walls of the conveying tracks (210 a-21) are arranged on two sides of the bearing plate (220).

7. The vertical rotary multi-station centrifugal drying apparatus according to claim 6, wherein the feeding mechanism (300) comprises a discharging assembly (310) mounted on the top of the supporting frame (210 a-1) and used for moving a plastic basket adjacent to the top of the bearing plate (220) of the drying drum (120) out of the top of the bearing plate (220), and a guiding assembly (320) mounted on the top of the outer drum body (110 a) and having two ends respectively corresponding to the output end of the discharging assembly (310) and a plurality of fixing grooves.

8. The vertical-type rotary multi-station spin-drying apparatus according to claim 7, wherein a side wall of one of the track wheels (210 a-2) of the inner wall of the housing (210 a) remote from the driving motor (230) is connected to a first pulley (210 a-22) through a rotation shaft;

the discharging assembly (310) comprises a fixing frame (310 a) arranged at the top of the supporting frame (210 a-1), a discharging roller (310 b) arranged between the two fixing frames (310 a) and provided with a stirring plate on the surface, and a transmission assembly (310 c) which is in transmission connection with the discharging roller (310 b) and drives the material guiding assembly (320) to work when the discharging roller (310 b) rotates, wherein one side of the discharging roller (310 b) is connected with a second belt pulley (310 b-1) connected with the first belt pulley (210 a-22) through a belt through a rotating shaft.

9. The vertical rotary multi-station centrifugal drying apparatus according to claim 8, wherein a half-tooth gear (310 b-2) is provided at an end of the discharging roller (310 b) away from the second pulley (310 b-1), and a full-tooth gear (310 b-21) meshed with the half-tooth gear (310 b-2) is provided at a side wall of the fixing frame (310 a);

the transmission assembly (310 c) comprises a first bevel gear set (310 c-1) with one end connected with the side wall of the full-tooth gear (310 b-21) and a third belt pulley (310 c-2) connected with the other end of the first bevel gear set (310 c-1).

10. The vertical rotary multi-station centrifugal drying device according to claim 9, wherein a clamping groove (110 a-1) is formed in the top of the outer barrel body (110 a), a mounting plate (110 a-2) is arranged on the top of the outer barrel body (110 a), and a limiting cylinder (110 a-21) with a limiting groove (110 a-211) on the inner wall is connected to the bottom of the mounting plate (110 a-2) through a connecting frame;

an elastic pawl is arranged at the output end of the rotating motor (110 b-1), and a pawl groove matched with the elastic pawl is arranged at the bottom of the spin dryer tube (120);

a connecting shaft (120 c) is arranged at the top of the inner wall of the spin dryer tube (120), a limiting column (120 c-1) matched with the limiting tube (110 a-21) is arranged at the top of the connecting shaft (120 c), and a reciprocating screw rod (120 c-2) is arranged at the top of the limiting column (120 c-1);

the guide assembly (320) comprises a fixed basket (320 a) which is clamped in the clamping groove (110 a-1) and is close to one side of the bearing plate (220) and is of an opening structure, and a guide frame (320 b) which is rotatably connected to the inner wall of the fixed basket (320 a) and is of an opening structure at two ends, one end, far away from the bearing plate (220), of the guide frame (320 b) is connected with a fourth belt pulley (320 b-1) which is connected with a third belt pulley (310 c-2) through a belt through a rotating shaft, the side wall of the fourth belt pulley (320 b-1) is connected with a second umbrella gear set (320 b-2) which is installed at the bottom of the mounting plate (110 a-2) and is provided with a threaded cylinder (320 b-21) at the other end, and the threaded cylinder (320 b-21) is matched with the reciprocating screw rod (120 c-2).