CN222402017U - Cup intelligent coating apparatus for producing - Google Patents

Abstract

The utility model relates to an intelligent cup coating production device, including a main shell body that constructs a processing space, the main shell body is partitioned and installed with a powder spraying component and a powder melting component on its side wall along the axial direction in a manner that the spraying process and the hot melt solidification process are completed in the shell cavity defined by the main shell body, a transverse slide rail that can slide out of its shell cavity is arranged on the inner bottom surface of the main shell body, and a clamping turntable that can drive a number of circumferentially spaced cup workpieces to synchronously revolve and rotate is slidably installed on the transverse slide rail; the bottom of the main shell body is also provided with a lifting component that is adjustably connected to the clamping turntable and supports it to be axially lifted in a manner that penetrates its bottom shell wall; a thermal circulation component that cools the powder melting component is also provided on the side of the main shell body. The utility model can improve the uniformity of spraying by completing the spraying process and the solidification process by partitioning and setting a planetary rotating clamping structure.

Description

Cup intelligent coating apparatus for producing

Technical Field

The utility model relates to the technical field of coating production equipment, in particular to an intelligent cup coating production device.

Background

When the cup product is produced, the outer side of the cup body needs to be sprayed, so that the appearance of the cup body is more attractive, and the corrosion resistance and the wear resistance of the cup body are improved. The spraying process is to spray the powder onto the surface of the workpiece, charge the powder with high voltage electrostatic equipment, spray the paint onto the surface of the workpiece under the action of electric field to form powder coating, bake the powder coating at high temperature and form one layer of dense protecting coating with different effect. The spraying plastic process has the advantages of no need of thinner, no pollution to environment, no toxicity to human body, excellent appearance quality of the coating, strong adhesive force and mechanical strength, short spraying curing time, high corrosion resistance and wear resistance of the coating, no need of primer, simple construction, low technical requirement on workers and lower cost than the spray painting process. Therefore, they are widely used in various fields.

The spraying process flow can be divided into spraying, uniformly distributing the paint on the surface of the sprayed metal component, solidifying, heating the surface paint of the sprayed product to a specified temperature and preserving heat for a corresponding time, so that the surface paint is melted, leveled and solidified, and the product achieves a corresponding surface effect.

Currently, in the conventional spray processing, workpieces are placed on a spray rack in batches, and the surfaces of the workpieces are subjected to multi-angle spray processing through spray equipment or a manual spray gun. However, the existing spraying equipment or manual spraying gun has poor spraying uniformity, the difference of coating thicknesses of different areas on the surface of a cup workpiece is easy to cause, the coating is easy to have concave-convex feeling, the surface smoothness is poor, and particularly, when the area with larger thickness of the coating is solidified by hot melting, the problem of forming a sagging block due to local melting and accumulation exists, so that the spraying quality is greatly reduced. In addition, the existing spraying equipment is provided with the spraying element and the solidifying element in the same space, so that part of scattered spraying powder is very easy to cause powder adhesion at the working end of the solidifying element to be blocked by melted powder, and the baking effect is affected. Finally, when the existing solidifying element is used for heating and drying, the working temperature of the heating lamp body is high and needs to be cooled regularly, but the conventional self-heat-dissipation cooling efficiency is low, the working interval time is long, and the spraying efficiency is reduced.

Disclosure of utility model

The utility model aims to provide an intelligent cup coating production device capable of improving spraying quality by improving spraying uniformity and heating uniformity through arranging a planetary rotary clamping structure while finishing spraying processing and curing processing in a partitioning way, so as to solve the problems that the existing manual spraying and traditional spraying equipment is low in spraying efficiency and poor in spraying quality, the cup coating subjected to spraying processing is uneven and smooth, a vertical block is easily formed in the hot-melting curing process to influence processing quality, the existing hot-melting curing heating body is too high in heating temperature to need long natural cooling time, the period of single spraying processing is prolonged, heat dissipated by direct cooling cannot be effectively recovered to cause waste of heat energy, and the utilization rate of energy sources is greatly reduced.

The intelligent cup coating production device comprises a main shell body for constructing a processing space, wherein the main shell body is provided with a powder spraying component and a powder melting component on the side wall of the main shell body in a partition manner according to the manner of finishing spraying treatment and hot melting solidification treatment in a defined shell cavity, a transverse sliding rail capable of sliding out of the shell cavity of the main shell body is arranged on the inner bottom surface of the main shell body, a clamping rotary table capable of driving a plurality of cup workpieces distributed at intervals in a circumferential direction to synchronously revolve and rotate is arranged on the transverse sliding rail in a sliding manner, the bottom of the main shell body is further provided with a lifting component capable of being butted with the clamping rotary table in a penetrating manner to support the main shell body to axially lift, and the side surface of the main shell body is further provided with a thermal circulation component capable of cooling the powder melting component.

According to a preferred embodiment, the clamping turntable comprises a planetary turntable, a clamping seat, a pedestal and a rotary driving motor, wherein the planetary turntable is rotatably installed on the pedestal, a rotation center shaft of the planetary turntable is in transmission connection with the rotary driving motor installed on the pedestal, and a plurality of rotation output ends of the planetary turntable are connected with the clamping seat.

According to a preferred embodiment, the rotating center shaft is inserted into a disc shell of the planetary turntable in a coaxial manner, a plurality of transmission teeth which are in transmission engagement with the rotating center shaft are further arranged in the disc shell at intervals along the axial direction, an inner gear ring capable of limiting the engagement state of the rotating center shaft and the transmission teeth is further arranged on the inner side wall surface of the disc shell, and a mounting column capable of extending to the outside of the disc shell is further inserted into the transmission teeth.

According to a preferred embodiment, the plurality of mounting posts are circumferentially arranged at intervals in a mode corresponding to the transmission teeth, the posts penetrate through a baffle disc for shielding an opening at the axial upper end of the disc shell, and the clamping seat is mounted at the axial upper end of each mounting post.

According to a preferred embodiment, the clamping seat comprises a seat body, a guide rod, a limiting spring, a clamping vertical plate and a baffle plate, wherein a plurality of guide grooves are formed in the upper surface of the seat body in a circumferential spacing mode, the guide rod is inserted into the guide grooves in a mode parallel to the guide grooves, the clamping vertical plate is sleeved on the guide rod in a sliding mode, the limiting spring is sleeved on the guide rod in a mode capable of limiting the position of the clamping vertical plate on the guide rod, and the baffle plate capable of shielding the guide grooves is sleeved on the clamping vertical plate.

According to a preferred embodiment, the shell cavity of the main shell is divided into a spraying shell cavity and a hot melting solidification shell cavity above the spraying shell cavity by a partition plate, through holes for the clamping rotary table to pass through are formed in the partition plate, and a shielding sliding plate capable of selectively shielding the through holes is further arranged on the upper side of the partition plate.

According to a preferred embodiment, two parallel transverse sliding rails are mounted on the inner bottom surface of the main housing in a manner of penetrating through the side walls of the spraying shell cavity, door leaves are further arranged on the side surfaces of the spraying shell cavity penetrated by the transverse sliding rails, and the pedestal is in rail connection with the transverse sliding rails.

According to a preferred embodiment, the housing shell of the lifting assembly is mounted at the bottom of the main housing, and a lifting column which can extend into the main housing is housed in the housing shell, and a magnetic attraction block is arranged at the axial upper end of the lifting column.

According to a preferred embodiment, the bottom surface of the pedestal is provided with a slot capable of accommodating at least part of the lifting column, and a magnetic metal plate capable of defining the connection state of the pedestal and the lifting column in cooperation with the magnetic block is further provided in the slot.

According to a preferred embodiment, the thermal cycle assembly comprises a heat absorption ring pipe surrounding the heat drying lamp group of the powder fusing assembly, a spiral pipeline surrounding the storage tank of the powder spraying assembly, and a connecting pipe communicating the heat absorption ring pipe and the spiral pipeline.

The beneficial effects of the utility model are as follows:

According to the application, the powder spraying component and the powder fusing component are separately arranged, so that the two working procedures can be carried out in a partitioned manner in stages, and shielding and obstruction of scattered spraying powder to functional elements of curing work are avoided, so that the effect and efficiency of hot baking are ensured. The transverse sliding rail provided by the application can complete the installation and position adjustment of the clamping turntable in a rapid butt joint mode, so that the clamping turntable can complete the coating processing and the workpiece dismounting work in a mode of moving in and out of the main shell, and the periodic maintenance and continuous processing production of the clamping turntable can be conveniently carried out in a mode of replacing the clamping turntable. In addition, the transferable guide rail can facilitate maintenance of the clamping structure when the shell cavity of the main shell is closed, so that impurities such as external dust can be prevented from polluting a processing space defined by the main shell. The clamping turntable provided by the application can carry out internal supporting limit on a plurality of cup workpieces in a rapid inserting mode, and can ensure that the inner cavity of the clamping turntable is not polluted in a cup opening sealing mode so as to improve the spraying quality. The clamping rotary table can drive a plurality of cup workpieces to rotate and revolve according to requirements, so that the relative positions of the cup workpieces, a powder spraying assembly and a powder fusing assembly which are arranged on the inner side wall of the main shell are continuously changed, the surface of the cup workpieces is uniformly sprayed with powder, the powder sprayed on the surface of the cup workpieces can be uniformly heated to melt and condense into a coating with high flatness, the smoothness of the coated coating is improved, a pituitary is avoided in the hot melting process, and the coating processing quality of the cup workpieces is improved. The lifting assembly provided by the application can be used for adjustably lifting and adjusting the clamping rotary table which is moved into the main shell, so that the clamping rotary table can be positioned at the spraying station and the fusing station according to requirements, different processing procedures can be completed in the separated space, and the processing quality is improved. The thermal circulation assembly provided by the application can construct a circulation cooling pipeline between the powder spraying assembly and the powder melting assembly, so that heat periodically transferred from the powder melting assembly can be transferred to the powder spraying assembly, thereby preheating powder, and further improving the efficiency and speed of subsequent hot melting processing. The heat circulation assembly can efficiently transfer excessive heat generated during the operation of the powder melting assembly, so that the periodic cooling buffering of heating elements of the powder melting assembly is realized, overheat damage is avoided, the utilization rate of heat energy is improved through heat recycling, the time of periodic shutdown and cooling of the powder melting assembly is shortened, the energy waste and the production cost of integral production can be reduced, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of a preferred intelligent coating production device for cups according to the present utility model;

FIG. 2 is a schematic view of a clamping turntable of a preferred intelligent cup coating production device according to the present utility model;

FIG. 3 is a schematic plan view of a holder of a preferred intelligent cup coating production device according to the present utility model;

FIG. 4 is a schematic view of a preferred intelligent coating production device for cup bodies according to the present utility model during the solidification process;

Fig. 5 is a schematic structural view of a preferred intelligent cup coating production device according to the present utility model when the clamping turntable is moved out of the shell cavity.

List of reference numerals

1, A main shell; the powder spraying device comprises a powder spraying component, a powder fusing component, a transverse sliding rail, a clamping rotary table, a lifting component, a thermal circulation component, a spraying shell cavity, a hot melt curing shell cavity, a baffle plate, a shielding slide plate, a door leaf, a through hole, a 21-part material tank, a 22-part material conveying pipe, a 23-part powder spraying unit, a 31-part heat drying lamp group, a 32-part blowing fan, a 51-part planetary rotary table, a 52-part clamping seat, a 53-part pedestal, a 54-part rotary driving motor, a 61-part containing shell, a 62-part lifting column, a 63-part magnetic attraction block, a 71-part heat absorption ring, a 72-part spiral pipeline, a 73-part connecting pipe, a 74-part heat exchange plate, a 511-part rotary center shaft, a 512-part shell, a 513-part driving gear, an inner gear ring, a 515-part mounting column, a 516-part baffle plate, a 521-part base body, a 522-part guide rod, a 523-part limiting spring, a 524-part clamping plate, a 525-part baffle plate, a 531-part slotted hole and a 532-part magnetic attraction metal plate.

Detailed Description

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the present utility model will be briefly described below with reference to the accompanying drawings and the description of the embodiments or the prior art, and it is obvious that the following description of the structure of the drawings is only some embodiments of the present utility model, and other drawings can be obtained according to these drawings without inventive effort to a person skilled in the art.

The technical solution provided by the present utility model will be described in detail by way of examples with reference to the accompanying drawings. It should be noted that the description of these examples is for aiding in understanding the present utility model, but is not intended to limit the present utility model. In some instances, some embodiments are not described or described in detail as such, as may be known or conventional in the art.

Furthermore, features described herein, or steps in all methods or processes disclosed, may be combined in any suitable manner in one or more embodiments in addition to mutually exclusive features and/or steps. It will be readily understood by those skilled in the art that the steps or order of operation of the methods associated with the embodiments provided herein may also be varied. Any order in the figures and examples is for illustrative purposes only and does not imply that a certain order is required unless explicitly stated that a certain order is required.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "connected" and "coupled" as used herein, where appropriate (without making up a paradox), include both direct and indirect connections (couplings).

The following detailed description refers to the accompanying drawings.

Example 1

The application provides an intelligent cup coating production device which comprises a main shell 1, a powder spraying assembly 2, a powder fusing assembly 3, a transverse sliding rail 4, a clamping rotary table 5, a lifting assembly 6 and a thermal circulation assembly 7.

According to a specific embodiment shown in fig. 1-5, the main housing 1 is able to build up a working space. The main casing 1 is provided with a powder spraying component 2 and a powder fusing component 3 on the side wall thereof in a partition manner in the axial direction in a manner of completing the spraying treatment and the hot melting curing treatment in the defined casing cavity. A transverse rail 4 which can slide out of its housing cavity is provided on the inner bottom surface of the main housing 1. A clamping rotary table 5 which can drive a plurality of cup body workpieces distributed at intervals in a circumferential direction to synchronously revolve and rotate is slidably arranged on the transverse sliding rail 4. The bottom of the main housing 1 is further provided with a lifting assembly 6 penetrating its bottom wall, which can be adjustably brought into abutment with the clamping turret 5 to support it for axial lifting. The side surface of the main casing 1 is also provided with a thermal cycle assembly 7 which can cool down and cool down the powder fusing assembly 3. The thermal circulation assembly 7 provided by the application can construct a circulation cooling pipeline between the powder spraying assembly 2 and the powder melting assembly 3, so that heat periodically transferred from the powder melting assembly 3 can be transferred to the powder spraying assembly 2, thereby preheating powder, and further improving the efficiency and speed of subsequent hot melting processing. The heat circulation assembly 7 can efficiently transfer excessive heat generated during the operation of the powder melting assembly 3, so that the periodic cooling buffering of heating elements is realized, overheat damage is avoided, the utilization rate of heat energy is improved through heat recycling, the time of periodic shutdown and cooling of the powder melting assembly 3 is shortened, the energy waste and the production cost of integral production can be reduced, and the production efficiency is improved. According to the application, the powder spraying component 2 and the powder fusing component 3 are separately arranged, so that two working procedures can be carried out in a staged and partitioned manner, and shielding and obstruction of scattered spraying powder to functional elements of curing work are avoided, so that the effect and efficiency of hot baking are ensured. The transverse sliding rail 4 provided by the application can complete the installation and position adjustment of the clamping turntable 5 in a rapid butt joint mode, so that the clamping turntable 5 can complete the coating processing and the workpiece dismounting work in a mode of moving in and out the main shell 1, and the periodic maintenance and continuous processing production of the clamping turntable 5 can be conveniently carried out in a mode of replacing the clamping turntable 5. In addition, the displaceable guide rail can facilitate maintenance of the clamping structure when closing the housing cavity of the main housing 1, so as to avoid contamination of the processing space defined by the main housing 1 by foreign substances such as external dust. The clamping turntable 5 provided by the application can carry out internal supporting limit on a plurality of cup workpieces in a rapid inserting mode, and can ensure that the inner cavity of the cup workpiece is not polluted in a cup opening sealing mode so as to improve the spraying quality. The clamping rotary table 5 can drive a plurality of cup workpieces to rotate and revolve according to requirements, so that the relative positions of the cup workpieces and the powder spraying assembly 2 and the powder fusing assembly 3 arranged on the inner side wall of the main shell 1 are continuously changed, the surface of the cup workpieces is uniformly sprayed with powder, the powder sprayed on the surface of the cup workpieces can be uniformly heated to melt and coagulate into a coating with high flatness, the smoothness of the coated coating is improved, a pituitary body is avoided in the hot melting process, and the coating processing quality of the cup workpieces is improved. The lifting assembly 6 provided by the application can adjustably lift and adjust the clamping rotary table 5 moved into the main shell 1, so that the clamping rotary table 5 can be positioned at a spraying station and a fusing station according to requirements, different processing procedures can be completed in separated spaces, and the processing quality is improved.

Preferably, the main housing 1 is divided into a spray housing 11 and a hot melt solidified housing 12 above the spray housing 11 by a partition 13. It is further preferred that the powder spray assembly 2 and the powder fusion assembly 3 are provided in the spray housing chamber 11 and the hot melt cure housing chamber 12, respectively. Preferably, the partition 13 is provided with a through hole 131 through which the clamping turret 5 passes. Further preferably, the aperture size of the through hole 131 is smaller than the largest cross-sectional area of the pedestal 53 of the clamping turntable 5, so that the raised clamping turntable 5 can effectively shield the through hole 131, and heat is prevented from escaping during the hot melting solidification process, and the diffusion of the hot melting substances is easy. Preferably, a shielding slide plate 14 capable of selectively shielding the through hole 131 is further provided on the upper side of the partition plate 13. Preferably, both sides of the shielding slide plate 14 are connected with the side cavity walls of the hot melt curing shell cavity 12 through slide rails so as to slidably and effectively shield the through holes 131. It is further preferred that the shutter sled 14 at least partially slides out of the hot melt curing shell cavity 12 in a manner that extends through the side cavity walls of the hot melt curing shell cavity 12 to adjust its operating position. Specifically, a sealing ring is arranged at the edge of the through hole on the side cavity wall of the hot-melt solidified shell cavity 12 so as to fill and shade the gap between the sliding plates 14 and ensure the tightness of the cavity. In use, the slide rail provided with the shielding slide plate 14 can drive the shielding slide plate 14 to transversely slide according to the movement of the lifting assembly 6 so as to adjustably shield or expose the through holes 131, thereby selectively separating the spraying shell cavity 11 and the hot-melt curing shell cavity 12 in cooperation with the partition plate 13 according to the processing procedure.

Preferably, the powder spray assembly 2 includes a reservoir 21 disposed outside of the spray housing chamber 11, a feed conduit 22 extending through the housing wall, and a powder spray unit 23 mounted on the inside wall of the spray housing chamber 11. Preferably, the powder spraying units 23 can be installed in a single set, or can be arranged in a plurality of sets at intervals in the circumferential direction. The powder spraying unit 23 preferably employs a conventional electrostatic powder spraying gun, which may be stationary or may be provided to move up and down along the mounting post, as desired. Preferably, the powder fusing assembly 3 further includes blowing fans 32 alternately arranged with the heat drying lamp set 31 on the annulus. Preferably, two parallel transverse rails 4 are mounted on the inner bottom surface of the main housing 1 in such a way as to extend through the side walls of the spray housing chamber 11. It is further preferred that the side of the spray housing chamber 11 penetrated by the transverse rail 4 is also provided with a door leaf 111. Preferably, the stand 53 is slidingly rail-mounted on the open track of the transversal slide 4 so that it can slide in or out of the main housing 1 along the transversal slide 4. Preferably, the door leaf 111 is able to block the side wall opening in cooperation with the transversal slide 4. According to the application, the powder spraying assembly 2 is distributed in a circumferential multi-station interval manner or in a single-station manner, and particularly the width of the axial storage opening of the powder spraying unit 23 is larger than the length of the cup body, so that the cup body workpiece passing through the working area can finish the spraying processing of the whole outer side wall in the rotation and revolution processes, and the uniformity and quality of spraying are ensured. The heat drying lamp set 31 provided by the application is matched with the blowing fan 32 to generate and directionally transfer heat, so that the high heat is utilized to carry out hot melting treatment on the coating on the surface of the cup workpiece, and the efficiency and quality of hot melting solidification are ensured.

Preferably, the clamping turntable 5 includes a planetary turntable 51, a clamping seat 52, a pedestal 53, and a rotation driving motor 54. Preferably, the planetary turntable 51 is rotatably mounted on a stand 53. Preferably, the central rotation shaft 511 of the planetary turntable 51 is in driving connection with a rotation driving motor 54 mounted on the pedestal 53. Preferably, a plurality of rotation output ends of the planetary turntable 51 are connected with a clamping seat 52. Specifically, the rotation center shaft 511 is inserted in a coaxial manner into the disk case 512 of the planetary turntable 51. A plurality of drive teeth 513 are preferably also disposed axially spaced within the disk housing 512 in driving engagement with the central axis of rotation 511. Further preferably, the inner side wall surface of the disk case 512 is further provided with an inner gear ring 514 capable of defining the engagement state of the rotation center shaft 511 and the driving teeth 513. Preferably, a mounting post 515 is also inserted into the gear 513, which can extend to the outside of the disk housing 512. Preferably, the plurality of mounting posts 515 are circumferentially spaced in correspondence with the driving teeth 513 and the posts thereof extend through a baffle plate 516 that shields the axially upper end opening of the disc housing 512. Preferably, the blocking disk 516 is rotatably embedded on the inner sidewall of the disk case 512, and the axial lower end of the mounting post 515 is movably inserted in a ring groove formed in the bottom of the disk case 512 to rotate in the direction of the groove. Preferably, the mounting post 515 has a clamping seat 52 mounted at an axially upper end thereof. The planetary turntable 51 provided by the application can drive a plurality of cup workpieces distributed at intervals to rotate and revolve according to requirements, so that the surface of the cup is coated with a coating with higher flatness more effectively, and the uniformity and quality of coating are ensured.

Preferably, the clamping seat 52 includes a seat 521, a guide bar 522, a limit spring 523, a clamping riser 524, and a baffle 525. Preferably, the upper surface of the base 521 is provided with a plurality of guide grooves 5211 circumferentially spaced apart. It is further preferable that the guide bar 522 is inserted in the guide groove 5211 in parallel with the guide groove 5211. Preferably, a clamping riser 524 is slidably received over the guide bar 522. Preferably, the limit spring 523 is sleeved on the guide bar 522 in a manner that can define the position of the clamp riser 524 on the guide bar 522. Further preferably, a baffle 525 capable of shielding the guide groove 5211 is further provided on the holding riser 524. Preferably, the clamping riser 524 includes a vertical arc plate capable of being effectively attached to an inner wall surface of the cup-shaped workpiece and a centripetal sloping plate arranged at the upper end of the vertical arc plate, so that the cup-shaped workpiece can be quickly inserted into an outer annular surface of an inner support limiting structure constructed by the plurality of clamping risers 524 in a matched manner. Preferably, the baffle 525 cooperates with the base 521 to form a supporting bottom surface without gaps to effectively shield the ports of the cup workpiece. It is further preferred that the surfaces of the baffle 525 and the seat 521 are provided with an elastic silica gel layer to ensure the shielding tightness of the cup workpiece port. Preferably, the bottom surface of the stand 53 is provided with a slot 531 capable of receiving at least part of the lifting column 62. Preferably, a magnetic metal plate 532 capable of defining a connection state of the pedestal 53 and the lifting column 62 in cooperation with the magnetic block 63 is further provided in the slot 531. The clamping seat 52 provided by the application can effectively clamp the cup body workpiece through the annular multi-region internal support positioning, and can also effectively shield the end face opening of the cup body workpiece, so that the clamping stability during spraying and the accuracy of a spraying region are ensured. The stand 53 of the present application is configured to be movable to facilitate rapid conversion of various movement conditions to facilitate locating the processing stations in different positions and on different planes.

Preferably, the housing envelope 61 of the lifting assembly 6 is mounted at the bottom of the main housing 1. Preferably, the accommodating case 61 accommodates therein a lifting column 62 that can extend into the main casing 1. Further preferably, the lifting column 62 is provided with a magnetic block 63 at an axial upper end thereof. The lifting column 62 provided by the application can change the station of the clamping rotary table 5 by adjustably positioning and lifting, so that the clamping rotary table 5 capable of realizing station adjustment in a horizontal plane by reciprocating sliding on the transverse sliding rail 4 can be subjected to vertical station adjustment under the action of the lifting column 62 to position different spraying stations and thermosetting stations.

Preferably, the thermal cycle assembly 7 includes a heat absorption loop 71 surrounding the heat drying lamp set 31 of the powder fusing assembly 3, a screw line 72 surrounding the material storage tank 21 of the powder spraying assembly 2, and a connection pipe 73 connecting the heat absorption loop 71 and the screw line 72 to construct a closed loop heat transfer line. Further preferably, the spiral pipeline 72 can be used for synchronously wrapping the storage tank 21 and the spraying shell cavity 11, so that the transferred heat can heat the storage tank 21 and also can preheat the spraying shell cavity 11, the temperature of powder and the initial temperature of a cup workpiece in the spraying shell cavity 11 are improved, and the powder can be quickly heated and melted in the hot melting and solidification process, and meanwhile the contact effectiveness between the powder and the cup workpiece is ensured, so that the powder can be more effectively adhered to the surface of the cup workpiece. Preferably, the spiral pipe 72 is further provided with heat exchange fins 74 on the surface thereof which is attached to the storage tank 21. Preferably, a driving liquid pump for driving the cooling liquid to flow in a directional manner is further provided in the connection pipe 73.

The utility model is not limited to the above-described alternative embodiments, and any person who may derive other various forms of products in the light of the present utility model, however, any changes in shape or structure thereof, all falling within the technical solutions defined in the scope of the claims of the present utility model, fall within the scope of protection of the present utility model. It should be understood by those skilled in the art that the present description and drawings are illustrative and not limiting to the claims. The scope of the utility model is defined by the claims and their equivalents. Throughout this document, the word "preferably" is used in a generic sense to mean only one alternative, and not to be construed as necessarily required, so that the applicant reserves the right to forego or delete the relevant preferred feature at any time.

Claims (10)

1. An intelligent cup coating production device comprises a main shell (1) for constructing a processing space, and is characterized in that,

The main shell (1) is provided with a powder spraying component (2) and a powder melting component (3) on the side wall along the axial direction in a partition way in a mode of completing spraying treatment and hot melting solidification treatment in a defined shell cavity,

A transverse sliding rail (4) capable of sliding out of a shell cavity of the main shell (1) is arranged on the inner bottom surface of the main shell, and a clamping turntable (5) capable of driving a plurality of cup workpieces distributed at intervals in a circumferential direction to synchronously revolve and rotate is slidably arranged on the transverse sliding rail (4);

The bottom of the main shell (1) is also provided with a lifting component (6) which can be adjustably butted with the clamping turntable (5) to support the main shell to axially lift in a way of penetrating through the bottom shell wall;

The side surface of the main shell (1) is also provided with a thermal circulation assembly (7) which can cool down and cool down the powder fusing assembly (3).

2. The intelligent cup coating production device according to claim 1, wherein the clamping turntable (5) comprises a planetary turntable (51), a clamping seat (52), a pedestal (53) and a rotary driving motor (54), wherein,

The planetary turntable (51) is rotatably mounted on the pedestal (53), and a rotation center shaft (511) of the planetary turntable (51) is in transmission connection with the rotation driving motor (54) mounted on the pedestal (53);

The plurality of rotation output ends of the planetary turntable (51) are connected with the clamping seat (52).

3. The intelligent coating production device for the cup body, as set forth in claim 2, characterized in that the rotation center shaft (511) is inserted into a disc shell (512) of the planetary turntable (51) in a coaxial manner, and a plurality of transmission teeth (513) which are in driving engagement with the rotation center shaft (511) are also arranged in the disc shell (512) at intervals along the axial direction,

The inner side wall surface of the disc shell (512) is also provided with a rotating center shaft (511) and a rotating center shaft

An inner gear ring (514) in the meshed state of the transmission gear (513);

A mounting post (515) which can extend to the outside of the disk housing (512) is also inserted into the gear (513).

4. A cup intelligent coating production device as claimed in claim 3, wherein a plurality of the mounting posts (515) are circumferentially arranged at intervals in a manner corresponding to the transmission teeth (513), and the posts penetrate through a baffle plate (516) for shielding an opening at the upper axial end of the plate shell (512);

the clamping seat (52) is mounted at the axial upper end of the mounting column (515).

5. The intelligent cup coating production device according to claim 4, wherein the clamping seat (52) comprises a seat body (521), a guide rod (522), a limit spring (523), a clamping vertical plate (524) and a baffle plate (525), wherein,

The upper surface of the base (521) is provided with a plurality of guide grooves (5211) at intervals in the circumferential direction, and the guide bar (522) is inserted in the guide groove (5211) in a manner parallel to the guide groove (5211),

The guide rod (522) is sleeved with the clamping vertical plate (524) in a sliding way,

The limiting spring (523) is sleeved on the guide rod (522) in a mode that the position of the clamping vertical plate (524) on the guide rod (522) can be limited;

The clamping vertical plate (524) is also sleeved with the baffle plate (525) which can shade the guide groove (5211).

6. The intelligent cup coating production device according to claim 5, wherein the main shell (1) is divided into a spraying shell cavity (11) and a hot melting solidification shell cavity (12) above the spraying shell cavity (11) by a partition plate (13);

The baffle (13) is provided with a through hole (131) for the clamping turntable (5) to pass through, and a shielding slide plate (14) capable of selectively shielding the through hole (131) is further arranged on the upper side of the baffle (13).

7. The intelligent cup coating production device according to claim 6, wherein two parallel transverse sliding rails (4) are installed on the inner bottom surface of the main shell (1) in a manner of penetrating through the side wall of the spraying shell cavity (11), and the side surface of the spraying shell cavity (11) penetrated by the transverse sliding rails (4) is further provided with a door leaf (111);

The pedestal (53) is in rail connection with the transverse sliding rail (4).

8. The intelligent cup coating production device according to claim 7, wherein a containing tube shell (61) of the lifting assembly (6) is installed at the bottom of the main shell (1), and a lifting column (62) capable of extending into the main shell (1) is contained in the containing tube shell (61),

The axial upper end of the lifting column (62) is provided with a magnetic attraction block (63).

9. The intelligent cup coating production device according to claim 8, wherein a slot (531) capable of accommodating at least part of the lifting column (62) is provided on the bottom surface of the pedestal (53), and a magnetic metal plate (532) capable of defining the connection state of the pedestal (53) and the lifting column (62) in cooperation with the magnetic block (63) is further provided in the slot (531).

10. The intelligent cup coating production device according to claim 9, wherein the thermal cycle assembly (7) comprises a heat absorption ring pipe (71) surrounding a heat drying lamp group (31) of the powder fusing assembly (3), a spiral pipeline (72) surrounding a storage tank (21) of the powder spraying assembly (2), and a connecting pipe (73) communicating the heat absorption ring pipe (71) and the spiral pipeline (72).