CN215964403U

CN215964403U - Coating device for processing conductive anti-static engineering plastics

Info

Publication number: CN215964403U
Application number: CN202122091835.0U
Authority: CN
Inventors: 沈爱华
Original assignee: Guangdong Liheng New Material Technology Co ltd
Current assignee: Guangdong Liheng New Material Technology Co ltd
Priority date: 2021-08-30
Filing date: 2021-08-30
Publication date: 2022-03-08
Anticipated expiration: 2031-08-30

Abstract

The utility model relates to the technical field of plastic processing devices, in particular to a coating device for conductive anti-static engineering plastic processing, which comprises a case, a feeding conveyor belt, a discharging conveyor belt, a circulating air heater, a material storage box and a cylindrical drying cavity, wherein one end of the circulating air heater is communicated with the interior of the cylindrical drying cavity through an air supply pipe, the other end of the circulating air heater is communicated with an air suction pipe, one end of a pump body is penetrated through the material storage box, the other end of the pump body is communicated with a spray head through a material conveying pipe, an infrared sensing device is arranged in the case through a connecting rod, and an electric telescopic rod and a partition are arranged on the case. According to the rotary type plastic product drying device, the two cleaning rollers which are clamped mutually are arranged at the feeding port, so that the plastic product can be pretreated before being cleaned, meanwhile, the inclined plate is arranged between the feeding conveying belt and the discharging conveying belt in the cylindrical drying cavity, and further, the plastic product can be dried in a rotary manner, so that the drying efficiency and the working efficiency after coating are greatly improved.

Description

Coating device for processing conductive anti-static engineering plastics

Technical Field

The utility model relates to the technical field of plastic processing devices, in particular to a coating device for processing conductive anti-static engineering plastics.

Background

Engineering plastics can be made engineering materials and replace plastics of metal manufacturing machine spare part etc. engineering plastics have good comprehensive properties, the rigidity is big, creep and diminish, mechanical strength is high, the heat resistance is good, electric insulation is good, can be in harsher chemistry, long-term use in the physical environment, the fungible metal uses as engineering structure material, in the outside coating material to engineering plastics, generally operate through the mode of manual spraying, like this at the in-process of coating, comparatively waste time and energy, and comparatively consume the manpower, secondly, after the spraying operation, can't carry out effective quick stoving operation to plastic products, and then greatly reduced work efficiency, for this reason, we have provided a coating device for the processing of electrically conductive antistatic engineering plastics.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects in the prior art, and provides a coating device for processing conductive anti-static engineering plastics.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a coating device for processing conductive anti-static engineering plastics comprises a case, a feeding conveyor belt, a discharging conveyor belt, a circulating hot air blower, a storage box and a cylindrical drying cavity, wherein one side of the inner wall of the case is provided with an inclined plate which is positioned between the feeding conveyor belt and the discharging conveyor belt, one side of a partition plate arranged on the inner wall of the case is attached to one side of the cylindrical drying cavity, one end of the circulating hot air blower penetrates through the top wall of the case through an air supply pipe, one end of the air supply pipe is communicated with the inside of the cylindrical drying cavity, the other end of the circulating hot air blower penetrates through the top wall of the case through an air suction pipe, one end of the air suction pipe is provided with an air collecting cover, one side of the top wall inside the case is provided with a pump body, one end of the pump body is communicated with the inside of the storage box, the other end of the pump body is communicated with a spray head through the air supply pipe, one side of the inner wall of the case is provided with an infrared induction device through a connecting rod, the upper portion of quick-witted case is provided with electric telescopic handle, and electric telescopic handle's pars contractilis runs through with the roof of quick-witted case, and electric telescopic handle's bottom face is provided with the wall.

Preferably, the both sides in tube-shape stoving chamber are uncovered, and the one end of feeding conveyer belt, the one end of exit conveyor and the one end of hang plate all extend to the inside in tube-shape stoving chamber.

Preferably, a controller is arranged in the case, heat dissipation plates are symmetrically arranged on two sides of the case close to the controller, an operation module is arranged on one side of the controller, and the controller is electrically connected with the electric telescopic rod, the circulating air heater, the pump body, the infrared induction device, the feeding conveyor belt, the discharging conveyor belt, the operation module and the cylindrical drying cavity respectively.

Preferably, the bottom end face of the partition is symmetrically provided with rollers, the middle part of the partition is provided with a through groove, and the through groove of the partition is matched with the partition.

Preferably, a plurality of air holes are uniformly formed in the inner wall of the cylindrical drying cavity.

Preferably, the two sides of the case are respectively provided with a feeding hole and a discharging hole, one end of the discharging conveyor belt penetrates through the discharging hole, and one end of the feeding conveyor belt penetrates through the feeding hole.

Preferably, the lower part of the feeding hole is rotatably provided with a first cleaning roller, and the first cleaning roller is connected with the shaft body of the feeding conveyor belt through the conveyor belt.

Preferably, the upper portion of feed inlet is provided with well cavity, and well cavity interpolation is equipped with T shape pole, rotates between the bottom face of T shape pole vertical part to be provided with the second cleaning roller, and the second cleaning roller is located first cleaning roller directly over.

Preferably, the top wall in the hollow cavity is provided with a first spring, the bottom end face of the first spring is fixedly connected with the top end face of the T-shaped rod horizontal portion, a second spring is sleeved on the outer side of the T-shaped rod vertical portion, and the second spring is located between the bottom end face of the T-shaped rod horizontal portion and the bottom wall in the hollow cavity.

The utility model has the beneficial effects that:

according to the rotary type plastic product drying device, the first cleaning roller and the second cleaning roller which are clamped with each other are arranged at the feeding opening, so that cleaning pretreatment operation can be performed on the plastic product to be coated, and then two sides of the plastic product are cleaned, and meanwhile, the inclined plate is arranged between the feeding conveying belt and the discharging conveying belt in the cylindrical drying cavity, so that the plastic product can be dried in a rotary manner, and the drying efficiency and the working efficiency after coating are greatly improved.

Drawings

FIG. 1 is a schematic structural diagram of a coating apparatus for processing conductive antistatic engineering plastics according to the present invention;

FIG. 2 is a schematic structural diagram of a coating apparatus for processing conductive antistatic engineering plastics according to the present invention;

FIG. 3 is an enlarged view of A in FIG. 2 of a coating apparatus for processing conductive antistatic engineering plastics according to the present invention;

fig. 4 is a front view of a coating apparatus for processing conductive antistatic engineering plastics according to the present invention.

In the figure: 1 case, 201 feeding conveyer belt, 202 discharging conveyer belt, 3 controller, 4 operation modules, 5 clapboards, 601 first cleaning roller, 602 second cleaning roller, 7 conveyer belt, 8T-shaped rod, 9 hollow cavity, 10 storage box, 111 connecting rod, 112 infrared sensing device, 121 first spring, 122 second spring, 13 pump body, 14 conveying pipeline, 15 spray nozzle, 16 electric telescopic rod, 17 partition, 18 rollers, 19 circulation air heater, 20 cylinder drying cavity, 211 air supply pipe, 212 air suction pipe, 22 air collecting cover, 23 inclined plate, 24 heat dissipation plate, 251 feeding port, 252 discharging port.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-4, a coating device for processing conductive anti-static engineering plastics comprises a case 1, a feeding conveyor belt 201, a discharging conveyor belt 202, a circulating hot air blower 19, a material storage box 10 and a cylindrical drying cavity 20, wherein a controller 3 is arranged in the case 1, heat dissipation plates 24 are symmetrically arranged on two sides of the case 1 close to the controller 3, an operation module 4 is arranged on one side of the controller 3, the controller 3 is respectively and electrically connected with an electric telescopic rod 16, the circulating hot air blower 19, a pump body 13, an infrared induction device 112, the feeding conveyor belt 201, the discharging conveyor belt 202, the operation module 4 and the cylindrical drying cavity 20, and an operator can use and control the coating device better by arranging the operation module 4;

a plurality of air holes are uniformly formed in the inner wall of the cylindrical drying cavity 20, both sides of the cylindrical drying cavity 20 are open, one end of the feeding conveyor belt 201, one end of the discharging conveyor belt 202 and one end of the inclined plate 23 extend into the cylindrical drying cavity 20, one side of the inner wall of the case 1 is provided with the inclined plate 23, the inclined plate 23 is located between the feeding conveyor belt 201 and the discharging conveyor belt 202, through the arrangement of the inclined plate 23, when a plastic product moves to the upper part of the discharging conveyor belt 202 along the feeding conveyor belt 201, the feeding conveyor belt 201 conveys the plastic product to the inclined plate 23, and then the plastic product slides to the discharging conveyor belt 202 along the inclined plate 23, so that the plastic product can be dried in a rotary manner;

one side of a partition plate 5 arranged on the inner wall of the case 1 is attached to one side of the cylindrical drying cavity 20, one end of a circulating hot air blower 19 is penetrated through the top wall of the case 1 through an air supply pipe 211, one end of the air supply pipe 211 is communicated with the interior of the cylindrical drying cavity 20, the other end of the circulating hot air blower 19 is penetrated through the top wall of the case 1 through an air suction pipe 212, and one end of the air suction pipe 212 is provided with an air collecting cover 22;

a pump body 13 is arranged on one side of the top wall in the case 1, one end of the pump body 13 is communicated with the inside of the material storage case 10, the other end of the pump body 13 is communicated with a spray head 15 through a material conveying pipe 14, an infrared sensing device 112 is arranged on one side of the inner wall of the case 1 through a connecting rod 111, and a starting signal can be timely transmitted into the controller 3 through the infrared sensing device 112 when a plastic product is fed;

a feeding hole 251 and a discharging hole 252 are respectively arranged on two sides of the case 1, one end of the discharging conveyor belt 202 penetrates through the discharging hole 252, one end of the feeding conveyor belt 201 penetrates through the feeding hole 251, a first cleaning roller 601 is rotatably arranged on the lower portion of the feeding hole 251, the first cleaning roller 601 is connected with a shaft body of the feeding conveyor belt 201 through a conveyor belt 7, a hollow cavity 9 is arranged on the upper portion of the feeding hole 251, a T-shaped rod 8 is inserted into the hollow cavity 9, a second cleaning roller 602 is rotatably arranged between bottom end faces of vertical portions of the T-shaped rods 8, the second cleaning roller 602 is located right above the first cleaning roller 601, and the feeding hole 251 is provided with the first cleaning roller 601 and the second cleaning roller 602 which are clamped with each other, so that cleaning pretreatment operation can be performed on a plastic product to be coated, and then two sides of the plastic product are cleaned;

a first spring 121 is arranged on the top wall inside the hollow cavity 9, the bottom end face of the first spring 121 is fixedly connected with the top end face of the horizontal part of the T-shaped rod 8, a second spring 122 is sleeved on the outer side of the vertical part of the T-shaped rod 8, the second spring 122 is located between the bottom end face of the horizontal part of the T-shaped rod 8 and the bottom wall inside the hollow cavity 9, the first spring 121 and the second spring 122 have good elastic potential energy, and the first spring 121 and the second spring 122 are matched with each other for use, so that the second cleaning roller 602 can better press the first cleaning roller 601, the cleaning roller is better suitable for plastic products with different thicknesses, and the cleaning efficiency is greatly improved;

the upper portion of machine case 1 is provided with electric telescopic handle 16, electric telescopic handle 16's pars contractilis runs through with the roof of machine case 1, and electric telescopic handle 16's bottom face is provided with cuts off 17, the bottom face symmetry that cuts off 17 is provided with gyro wheel 18, the middle part of baffle 5 is provided with logical groove, and 5 logical groove of baffle and cut off 17 looks adaptation, through set up gyro wheel 18 under cutting off 17, when electric telescopic handle 16 drives to cut off 17 and feed conveyor 201 and paste mutually, it can with feed conveyor 201's conveying looks adaptation to cut off gyro wheel 18 under 17, thereby avoid cutting off 17 and produce wearing and tearing to feed conveyor 201.

In this embodiment, an operator puts a plastic product to be coated on a feeding conveyor belt 201 in a chassis 1 along a feeding port 251, a first cleaning roller 601 is rotatably arranged at the lower part of the feeding port 251, the first cleaning roller 601 is connected with a shaft body of the feeding conveyor belt 201 through a conveyor belt 7, a T-shaped rod 8 and a second cleaning roller 602 are inserted into a hollow cavity 9 at the upper part of the feeding port 251, and the feeding port 251 is provided with the first cleaning roller 601 and the second cleaning roller 602 which are clamped with each other, so that a cleaning pretreatment operation can be performed on the plastic product to be coated, and then two sides of the plastic product are cleaned;

the top wall in the hollow cavity 9 is provided with a first spring 121, the outer side of the vertical part of the T-shaped rod 8 is sleeved with a second spring 122, the first spring 121 and the second spring 122 both have good elastic potential energy, and the first spring 121 and the second spring 122 are matched with each other for use, so that the second cleaning roller 602 can better press the first cleaning roller 601, and therefore, the cleaning device is better suitable for plastic products with different thicknesses, and the cleaning efficiency is greatly improved;

when the plastic product moves to the infrared sensing device 112 along the feeding conveyor belt 201, the infrared sensing device 112 drives the nozzle 15 to perform coating operation on the plastic product, and when the extension part of the electric telescopic rod 16 drives the partition 17 to be attached to the feeding conveyor belt 201, the roller 18 below the partition 17 can be matched with the conveying of the feeding conveyor belt 201, so that the partition 17 is prevented from abrading the feeding conveyor belt 201;

further, after the coating operation is finished, the extension part of the electric telescopic rod 16 drives the partition 17 to reset, the plastic product enters the cylindrical drying cavity 20 along the feeding conveyor belt 201, a plurality of air holes are uniformly formed in the inner wall of the cylindrical drying cavity 20, both sides of the cylindrical drying cavity 20 are open, one end of the feeding conveyor belt 201, one end of the discharging conveyor belt 202 and one end of the inclined plate 23 extend into the cylindrical drying cavity 20, the inclined plate 23 is arranged on one side of the inner wall of the case 1, and the inclined plate 23 is located between the feeding conveyor belt 201 and the discharging conveyor belt 202;

when the plastic product moves above the discharging conveyor belt 202 along the feeding conveyor belt 201, the feeding conveyor belt 201 conveys the plastic product to the inclined plate 23, and then the plastic product slides to the discharging conveyor belt 202 along the inclined plate 23, so that the plastic product can be dried in a rotary manner;

through the first cleaning roller and the second cleaning roller that set up mutual centre gripping in feed inlet department, can clean the preliminary treatment operation to the plastic products who carries out the coating, and then clean the both sides of plastic products, simultaneously through set up the hang plate between feeding conveyer belt and the exit conveyor at the tube-shape stoving intracavity, and then can carry out the rotation stoving to plastic products to drying efficiency and work efficiency after the coating have been improved greatly.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims

1. A coating device for processing conductive anti-static engineering plastics comprises a case (1), a feeding conveyor belt (201), a discharging conveyor belt (202), a circulating air heater (19), a storage box (10) and a cylindrical drying cavity (20), and is characterized in that one side of the inner wall of the case (1) is provided with an inclined plate (23), the inclined plate (23) is positioned between the feeding conveyor belt (201) and the discharging conveyor belt (202), one side of a partition plate (5) arranged on the inner wall of the case (1) is attached to one side of the cylindrical drying cavity (20), one end of the circulating air heater (19) is penetrated through the top wall of the case (1) through an air supply pipe (211), one end of the air supply pipe (211) is communicated with the inside of the cylindrical drying cavity (20), the other end of the circulating air heater (19) is penetrated through the top wall of the case (1) through an air suction pipe (212), and one end of the air suction pipe (212) is provided with an air collecting cover (22), one side of the top wall in the case (1) is provided with a pump body (13), one end of the pump body (13) is communicated with the inside of the material storage box (10), the other end of the pump body (13) is communicated with a spray head (15) through a material conveying pipe (14), one side of the inner wall of the case (1) is provided with an infrared sensing device (112) through a connecting rod (111), the upper part of the case (1) is provided with an electric telescopic rod (16), the telescopic part of the electric telescopic rod (16) is penetrated through the top wall of the case (1), and the bottom end face of the electric telescopic rod (16) is provided with a partition wall (17).

2. The coating device for processing the conductive antistatic engineering plastic as claimed in claim 1, wherein both sides of the cylindrical drying cavity (20) are open, and one end of the feeding conveyor belt (201), one end of the discharging conveyor belt (202) and one end of the inclined plate (23) extend to the inside of the cylindrical drying cavity (20).

3. The coating device for processing the conductive anti-static engineering plastic according to claim 1, wherein a controller (3) is arranged in the case (1), heat dissipation plates (24) are symmetrically arranged on two sides of the case (1) close to the controller (3), an operation module (4) is arranged on one side of the controller (3), and the controller (3) is electrically connected with the electric telescopic rod (16), the circulating hot air blower (19), the pump body (13), the infrared sensing device (112), the feeding conveyor belt (201), the discharging conveyor belt (202), the operation module (4) and the cylindrical drying cavity (20) respectively.

4. The coating device for processing the conductive antistatic engineering plastic as claimed in claim 1, wherein the bottom end face of the partition (17) is symmetrically provided with rollers (18), the middle part of the partition (5) is provided with a through groove, and the through groove of the partition (5) is matched with the partition (17).

5. The coating device for processing the conductive antistatic engineering plastic as claimed in claim 1, wherein a plurality of air holes are uniformly arranged on the inner wall of the cylindrical drying cavity (20).

6. The coating device for processing the conductive antistatic engineering plastic as claimed in claim 1, wherein a feed port (251) and a discharge port (252) are respectively arranged at two sides of the case (1), one end of the discharge conveyor belt (202) is penetrated through the discharge port (252), and one end of the feed conveyor belt (201) is penetrated through the feed port (251).

7. The coating device for processing the conductive antistatic engineering plastic as claimed in claim 6, wherein a first cleaning roller (601) is rotatably arranged at the lower part of the feeding hole (251), and the first cleaning roller (601) is connected with the shaft body of the feeding conveyor belt (201) through a conveyor belt (7).

8. The coating apparatus for processing conductive antistatic engineering plastics according to claim 6, wherein a hollow cavity (9) is arranged at the upper part of the feed inlet (251), a T-shaped rod (8) is inserted into the hollow cavity (9), a second cleaning roller (602) is rotatably arranged between the bottom end surfaces of the vertical parts of the T-shaped rod (8), and the second cleaning roller (602) is positioned right above the first cleaning roller (601).

9. The coating device for processing conductive antistatic engineering plastics according to claim 8, wherein the top wall inside the hollow cavity (9) is provided with a first spring (121), the bottom end surface of the first spring (121) is fixed to the top end surface of the horizontal part of the T-shaped rod (8) through connection, the outer side of the vertical part of the T-shaped rod (8) is sleeved with a second spring (122), and the second spring (122) is located between the bottom end surface of the horizontal part of the T-shaped rod (8) and the bottom wall inside the hollow cavity (9).