CN213924986U - Vacuum coating device with feeding structure - Google Patents

Abstract

The utility model discloses a vacuum coating device with pay-off structure, including vacuum coating shell, coating film supporting body, evaporimeter subassembly, solution side channel, infrared distance meter, controller, fortune carrier band, baffle, feeding bin, conveyer belt, conveying passageway, vibrating motor, connection extension board and foreign body storehouse, the solution side channel is installed in the left side of evaporimeter subassembly, and installs infrared distance meter above the solution side channel, infrared distance meter's the vertical controller that has in top, the upper right side of evaporimeter subassembly is provided with fortune carrier band, and the surface mounting of fortune carrier band has the baffle, the right side of fortune carrier band is provided with feeding bin, and feeding bin's right side installs conveying passageway, conveying passageway's inner wall is fixed with vibrating motor, and vibrating motor's output is connected with the connection extension board. The vacuum coating device can monitor the depth of the solution side groove in real time, and can automatically control motors of the carrying belt and the conveying belt to realize automatic feeding to the inside.

Description

Vacuum coating device with feeding structure

Technical Field

The utility model relates to a vacuum coating technical field, specific vacuum coating device with pay-off structure that says so.

Background

Vacuum coating refers to a method for forming a thin film by heating a metal or non-metal material under a high vacuum condition to evaporate and condense the metal or non-metal material on the surface of a plated part (metal, semiconductor or insulator), such as vacuum aluminum plating, vacuum chromium plating, etc. currently, vacuum coating is not sufficient in time for a material, and a supplemented material is doped with other impurities to cause impure solution, and therefore, a vacuum coating device with a feeding structure is provided to solve the above problems.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims at providing a vacuum coating device with a feeding structure.

The utility model discloses a realize that the technical scheme that above-mentioned purpose adopted is: a vacuum coating device with a feeding structure comprises a vacuum coating shell, a coating bearing body, an evaporator component, a solution side groove, an infrared distance meter, a controller, a carrying belt, a baffle, a feeding bin, a conveyor belt, a conveying channel, a vibration motor, a connecting support plate and an impurity bin, wherein the coating bearing body is arranged inside the vacuum coating shell, the evaporator component is arranged below the coating bearing body, the solution side groove is arranged on the left side of the evaporator component, the infrared distance meter is arranged above the solution side groove, the controller is vertically arranged above the infrared distance meter, the carrying belt is arranged on the upper right side of the evaporator component, the baffle is arranged on the outer surface of the carrying belt, the feeding bin is arranged on the right side of the carrying belt, the conveying channel is arranged on the right side of the feeding bin, the vibration motor is fixed on the inner wall of the conveying channel, and the output end of the vibration motor is connected with the connecting support plate, an impurity bin is installed on the right side of the feeding bin, and a conveying belt is installed above the impurity bin.

The evaporator assembly and the coating supporting body are positioned in the same vertical direction, and a communicating structure is formed between the solution side groove and the evaporator assembly.

The measurement of infrared distance meter is vertical downwards, and electric connection between infrared distance meter and the controller.

The carrying belt is designed in an inclined mode, and the baffles are located on the outer surface of the carrying belt and distributed at equal intervals.

The conveying belt built-in motor is electrically connected with the controller, and a communicating structure is formed between the conveying channel and the feeding bin.

The connecting support plate is tightly attached to the lower surface of the conveyor belt, and the surface of the conveyor belt is designed to be a hollow structure.

The utility model has the advantages that: this device can be real-time the volume of the solution of storing in the evaporator assembly of embodiment department through the solution side groove that keeps communicating structure design with the evaporator assembly, and the utilization can the depth of real-time supervision solution side groove, and then realize the detection to the automatic capacity of the inside solution of evaporator assembly, and the motor of connection through the controller can automated control fortune carrier band and conveyer belt, utilize motor drive fortune carrier band and baffle to make automatic to the inside pay-off of evaporator assembly, very big use of saving manpower, and the condition of omitting can not take place, and can utilize vibrating motor's vibrations effect with material and impurity separation, improve the cleanness of material, and then improve the quality of coating film.

Drawings

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

FIG. 2 is a schematic diagram of a side view structure of the vibration motor of the present invention;

fig. 3 is a schematic view of the structure of the solution side groove of the present invention.

In the figure: 1. vacuum coating the outer casing; 2. coating a film carrier; 3. an evaporator assembly; 4. a solution side tank; 5. an infrared range finder; 6. a controller; 7. carrying a belt; 8. a baffle plate; 9. a feeding bin; 10. a conveyor belt; 11. a transfer channel; 12. a vibration motor; 13. connecting the support plate; 14. impurity storehouse.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, a vacuum coating device with a feeding structure comprises a vacuum coating shell 1, a coating carrier 2, an evaporator assembly 3, a solution side groove 4, an infrared distance meter 5, a controller 6, a carrier belt 7, a baffle 8, a feeding bin 9, a conveyor belt 10, a conveying channel 11, a vibration motor 12, a connecting support plate 13 and an impurity bin 14, wherein the coating carrier 2 is installed inside the vacuum coating shell 1, the evaporator assembly 3 is arranged below the coating carrier 2, the solution side groove 4 is installed on the left side of the evaporator assembly 3, the infrared distance meter 5 is installed above the solution side groove 4, the controller 6 is vertically arranged above the infrared distance meter 5, the carrier belt 7 is arranged on the upper right side of the evaporator assembly 3, the baffle 8 is installed on the outer surface of the carrier belt 7, the feeding bin 9 is arranged on the right side of the carrier belt 7, and the conveying channel 11 is installed on the right side of the feeding bin 9, the inner wall of conveying channel 11 is fixed with vibrating motor 12, and the output of vibrating motor 12 is connected with and connects extension board 13, and the right side of feeding bin 9 is installed impurity storehouse 14, and the conveyer belt 10 is installed to the top of impurity storehouse 14.

The utility model discloses in, evaporator assembly 3 and coating film supporting body 2 are located same vertical direction, and constitute the connectivity structure between solution side groove 4 and the evaporator assembly 3, can make the inside solution of evaporator assembly 3 transmit to the inside of solution side groove 4 through the structural design of intercommunication, and the infrared distance meter 5 of being convenient for carries out the detection of degree of depth.

The measurement of infrared distance measuring instrument 5 is vertical down, and electric connection between infrared distance measuring instrument 5 and the controller 6, and the operation of realizing automation through controller 6 carries out the pay-off, and very big using manpower sparingly, and can not produce the condition emergence of forgetting.

The carrying belt 7 is designed in an inclined mode, the baffles 8 are located on the outer surface of the carrying belt 7 and distributed at equal intervals, materials in the feeding bin 9 can be carried to the maximum extent through the baffles 8 designed in an inclined mode, carrying efficiency is improved, and energy conservation and emission reduction are achieved.

The built-in motor of the carrying belt 7 is electrically connected with the controller 6, a communicating structure is formed between the conveying channel 11 and the feeding bin 9, materials and impurities can be screened by driving of the vibration motor 12, and the quality of a coating film is further improved.

Closely laminate between the lower surface of connecting extension board 13 and conveyer belt 10, and conveyer belt 10 surface adopts the hollow out construction design, and the conveyer belt 10 through the hollow out construction design is convenient for the transportation of material and arranges the sediment, and utilizes impurity storehouse 14 to be convenient for in time retrieve impurity.

The utility model discloses a theory of operation is: firstly, the device is externally connected with a power supply, when the materials stored in the feeding bin 9 are insufficient, the conveyor belt 10 is started, so that the motor in the conveyor belt 10 drives the hollow-out conveyor belt 10 to rotate anticlockwise, then the materials are poured into the right side of the conveying channel 11, the surface of the conveying belt 10 is vibrated by the vibration motor 12 and the connecting support plate 13, the materials are conveyed while slag is discharged, thus, the impurities fall into the impurity bin 14 to be stored therein, the solution side tank 4 is communicated with the evaporator unit 3, when the solution in the evaporator unit 3 is insufficient, the infrared distance meter 5 detects the depth of the solution-side tank 4 as reaching a specified depth, the carrier tape 7 is driven by a built-in motor through connection with the controller 6, the baffle 8 is driven to rotate anticlockwise, and then can transport the material of storing in the feed bin 9 left, and then transport the inside of evaporimeter subassembly 3 can.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. A vacuum coating device with a feeding structure is characterized by comprising a vacuum coating shell (1), a coating bearing body (2), an evaporator component (3), a solution side groove (4), an infrared distance meter (5), a controller (6), a carrying belt (7), a baffle plate (8), a feeding bin (9), a conveying belt (10), a conveying channel (11), a vibration motor (12), a connecting support plate (13) and an impurity bin (14), wherein the coating bearing body (2) is installed inside the vacuum coating shell (1), the evaporator component (3) is arranged below the coating bearing body (2), the solution side groove (4) is installed on the left side of the evaporator component (3), the infrared distance meter (5) is installed above the solution side groove (4), the controller (6) is vertically arranged above the infrared distance meter (5), the carrying belt (7) is arranged above the right side of the evaporator component (3), and the outer surface mounting of carrying area (7) has baffle (8), the right side of carrying area (7) is provided with feeding bin (9), and feeding bin's (9) right side installs conveying passageway (11), the inner wall of conveying passageway (11) is fixed with vibrating motor (12), and vibrating motor's (12) output is connected with and connects extension board (13), impurity storehouse (14) are installed on feeding bin's (9) right side, and conveyer belt (10) are installed to the top of impurity storehouse (14).

2. The vacuum coating apparatus with a feeding structure according to claim 1, wherein: the evaporator component (3) and the coating bearing body (2) are positioned in the same vertical direction, and a communicating structure is formed between the solution side groove (4) and the evaporator component (3).

3. The vacuum coating apparatus with a feeding structure according to claim 1, wherein: the measurement of infrared distance meter (5) is vertical downwards, and infrared distance meter (5) and controller (6) are electrically connected.

4. The vacuum coating apparatus with a feeding structure according to claim 1, wherein: the carrying belt (7) is designed in an inclined mode, and the baffle plates (8) are located on the outer surface of the carrying belt (7) and distributed at equal intervals.

5. The vacuum coating apparatus with a feeding structure according to claim 1, wherein: the internal motor of the carrying belt (7) is electrically connected with the controller (6), and a communicating structure is formed between the conveying channel (11) and the feeding bin (9).

6. The vacuum coating apparatus with a feeding structure according to claim 1, wherein: the connecting support plate (13) is tightly attached to the lower surface of the conveyor belt (10), and the surface of the conveyor belt (10) is designed to be a hollow structure.

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