CN117626214A - Coating device for aluminum alloy surface - Google Patents

Abstract

The invention discloses a coating device for an aluminum alloy surface, which belongs to the field of vacuum coating, and comprises a secondary module, wherein a sealing cover is hinged to the outer side of a cavity formed in the secondary module, a cylindrical cavity is formed in the side edge of a gas passing hole formed in the secondary module, a limiting ring is fixedly connected to the middle part of the cylindrical cavity, a first compression spring is placed in the middle part of the cylindrical cavity, a cylindrical block is slidingly connected to the middle part of the cylindrical cavity, light sensors are fixedly connected to the upper end and the lower end of the cylindrical cavity, one end, close to a main module, of the secondary module is fixedly connected to a frame, the upper end of the middle part of the frame is fixedly connected to a pressure sensor, and the middle part of the frame is slidingly connected to a sealing plate.

Description

Coating device for aluminum alloy surface

Technical Field

The invention relates to the field of vacuum coating, in particular to a coating device for an aluminum alloy surface.

Background

Vacuum coating refers to a method for forming a thin film by heating a metal or nonmetal material under high vacuum to evaporate and condense the material on the surface of a plated article.

In the production process of the aluminum alloy, in order to improve some characteristics of the aluminum alloy, vacuum coating is usually carried out on the aluminum alloy, in actual operation, the vacuum coating needs to be kept under vacuum conditions, and in-and-out materials need to return the coating environment to a standard air pressure state, so that the coating environment needs to be pumped into a vacuum state again during in-and-out materials each time, the in-and-out materials cannot be continuously carried out, and the working efficiency is reduced.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a coating device for the surface of an aluminum alloy, which can realize that the internal cavity of a main module is always kept in a vacuum state under the combined action of a secondary module and a main module, and the material vaporization module does not need to interrupt work in the feeding and discharging process, so that the working efficiency is improved.

2. Technical proposal

In order to solve the problems, the invention adopts the following technical scheme.

The coating device for the aluminum alloy surface comprises a main module, wherein the left end and the right end of the main module are fixedly connected with auxiliary modules;

the middle parts of the main module and the auxiliary module are respectively provided with an air passing hole, a cavity and a track module, the upper ends of the air passing holes are respectively provided with an air sucking pump, and the middle parts of the track modules are connected with a transportation rotation module in a sliding manner;

the middle part of the main module is provided with a material vaporization module, and the middle part of the transportation rotation module is clamped with a material hanging module;

the sealing cover is hinged to the outer side of a cavity formed in the auxiliary module, a cylindrical cavity is formed in the side edge of an air passing hole formed in the auxiliary module, a limiting ring is fixedly connected to the middle of the cylindrical cavity, a first compression spring is placed in the middle of the cylindrical cavity, a cylindrical block is slidably connected to the middle of the cylindrical cavity, light sensors are fixedly connected to the upper end and the lower end of the cylindrical cavity, and a frame is fixedly connected to one end, close to the main module, of the auxiliary module;

the upper end of the middle part of the frame is fixedly connected with a pressure sensor, the middle part of the frame is slidably connected with a sealing plate, racks are arranged at the edges of the sealing plate, servo motors are arranged at the middle parts of the left end and the right end of the frame, gears are fixedly connected with the output ends of the servo motors, rectangular grooves are arranged at the middle part of the lower end of the frame, a supporting block is slidably connected with the middle part of the rectangular grooves, two second compression springs are fixedly connected with the lower ends of the supporting blocks, and air passages are arranged at the lower ends of the rectangular grooves and positioned at the middle parts of the auxiliary modules;

the upper end of the middle part of the air passage is fixedly provided with a linkage device, the tail end of the air passage is positioned in the middle of the auxiliary module and is hinged with a cover disc, and the cavity in the main module is always kept in a vacuum state under the combined action of the auxiliary module and the main module, so that the material vaporization module does not need to interrupt work in the feeding and discharging process, and the working efficiency is improved.

Further, the linkage comprises two shells and two risers;

the middle part of the shell is connected with a push rod in a sliding way, an extension spring is placed in the middle part of the shell, and the upper ends of the two push rods are fixedly connected with a rectangular plate;

the one end fixedly connected with third compression spring that rectangular plate was kept away from to the riser, riser lower extreme fixedly connected with diaphragm, one side fixedly connected with fixture block that the riser upper end is close to the rectangular plate makes the inside pneumatic pressure of cavity resume to standard atmospheric pressure, and is difficult for taking place the gas leakage condition when cavity vacuum state.

Further, the one end that the gas pocket was kept away from to the cylindricality chamber is linked together with the external world, and the spacing ring carries out spacingly to first compression spring for the cylindricality piece can be moved to the spacing ring under the effect of atmospheric pressure, and the cylindricality piece is difficult for deviating from cylindricality chamber middle part.

Further, track module, transportation rotate module, material vaporization module, light sensor, aspiration pump, pressure sensor and servo motor electric connection, and gear and rack meshing are connected for track module, transportation rotate module, material vaporization module, light sensor, aspiration pump, pressure sensor and servo motor can the linkage work, and the gear can drive the rack motion.

Further, rectangular protruding blocks are arranged at the left end and the right end of the supporting block, and the sealing plate is located under the pressure sensor, so that the supporting block is not easy to deviate from the middle of the rectangular groove, and the sealing plate rises to trigger the pressure sensor.

Further, the cross section of the sealing plate is larger than that of the cavity, and the sealing plate is located right above the supporting block, so that the cavity can be sealed by the sealing plate, and the supporting block can be pressed down by the descending of the sealing plate.

Further, the through hole has been seted up at air flue middle part upper end in sub-module middle part, and rectangular plate and through-hole assorted for the air flue can be linked together with sub-module middle part cavity, and rectangular plate can block up the through-hole.

Further, the cover plate can rotate towards the inner side of the air passage, and the air passage can be blocked by the cover plate, so that the cover plate is not easy to block external air from entering the air passage, and the air in the middle of the air passage is not easy to enter the external environment from the end part.

Further, the shape of the upper end of the clamping block is arc-shaped, and the lower end of the clamping block limits the rectangular plate, so that the clamping block is not easy to block the rectangular plate from moving downwards, and the clamping block can limit the rectangular plate from moving upwards.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) According to the scheme, the auxiliary module and the main module are combined, so that the cavity in the main module is always kept in a vacuum state, the material vaporization module does not need to interrupt work in the feeding and discharging process, and the working efficiency is improved.

(2) The air passage and the linkage device enable the cavity in the middle of the auxiliary module to return to the normal air pressure state from the vacuum state.

(3) The cylindrical block and the light sensor enable the air pump to stop working after vacuumizing the cavity in the middle of the auxiliary module.

Drawings

FIG. 1 is an overall perspective view of the present invention;

FIG. 2 is a perspective view of the present invention in full semi-section;

FIG. 3 is an overall semi-cutaway view of the present invention;

FIG. 4 is a partial cutaway perspective view of the main module of the present invention;

FIG. 5 is a partial semi-cutaway perspective view of a secondary module of the present invention;

FIG. 6 is a partial enlarged partial A view of a sub-module of the present invention in partial semi-section;

FIG. 7 is a partial enlarged, partially cut-away view of a secondary module of the present invention;

FIG. 8 is a partial semi-sectional side perspective view of a secondary module of the present invention;

FIG. 9 is a partial enlarged view of a sub-module portion semi-section side perspective view of the present invention;

FIG. 10 is a perspective view of the linkage of the present invention;

FIG. 11 is a front elevational view, in full half section, of the present invention;

FIG. 12 is a schematic view of a sub-module in a vacuum state according to the present invention;

FIG. 13 is a schematic diagram of the loading state of the present invention;

fig. 14 is a partial enlarged D-chart of the feeding state of the present invention.

The reference numerals in the figures illustrate:

1. a main module; 2. a secondary module; 3. air passing holes; 4. an air extracting pump; 5. a cavity; 6. a track module; 7. a transportation rotation module; 8. a material vaporization module; 9. a hanging module; 10. sealing cover; 11. a cylindrical cavity; 12. a limiting ring; 13. a first compression spring; 14. a cylindrical block; 15. a light sensor; 16. a frame; 17. a pressure sensor; 18. a sealing plate; 19. a rack; 20. a servo motor; 21. a gear; 22. rectangular grooves; 23. a support block; 24. a second compression spring; 25. an airway; 26. a linkage; 2601. a housing; 2602. a push rod; 2603. a tension spring; 2604. a riser; 2605. a third compression spring; 2606. a cross plate; 2607. a clamping block; 2608. a rectangular plate; 27. and (5) a cover disc.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present invention are within the protection scope of the present invention.

In the description of the present invention, it should be noted that the positional or positional relationship indicated by the terms such as "upper", "lower", "inner", "outer", "top/bottom", etc. are based on the positional or positional relationship shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "configured to," "engaged with," "connected to," and the like are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of the element of the adapting model. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1-14, a coating device for an aluminum alloy surface comprises a main module 1, wherein the left and right ends of the main module 1 are fixedly connected with auxiliary modules 2;

wherein, the middle parts of the main module 1 and the auxiliary module 2 are respectively provided with an air passing hole 3, a cavity 5 and a track module 6, the upper ends of the air passing holes 3 are respectively provided with an air extracting pump 4, and the middle parts of the track modules 6 are slidably connected with a transportation rotation module 7;

the middle part of the main module 1 is provided with a material vaporization module 8, and the middle part of the transportation rotation module 7 is clamped with a material hanging module 9;

the outer side of a cavity 5 formed in the auxiliary module 2 is hinged with a sealing cover 10, a cylindrical cavity 11 is formed in the side edge of an air passing hole 3 formed in the auxiliary module 2, a limiting ring 12 is fixedly connected to the middle of the cylindrical cavity 11, a first compression spring 13 is placed in the middle of the cylindrical cavity 11, a cylindrical block 14 is slidingly connected to the middle of the cylindrical cavity 11, light sensors 15 are fixedly connected to the upper end and the lower end of the cylindrical cavity 11, and a frame 16 is fixedly connected to one end, close to the main module 1, of the auxiliary module 2;

the upper end of the middle part of the frame 16 is fixedly connected with a pressure sensor 17, the middle part of the frame 16 is slidably connected with a sealing plate 18, racks 19 are arranged at the edges of the sealing plate 18, servo motors 20 are arranged at the middle parts of the left end and the right end of the frame 16, the output ends of the servo motors 20 are fixedly connected with gears 21, a rectangular groove 22 is arranged at the middle part of the lower end of the frame 16, a supporting block 23 is slidably connected at the middle part of the rectangular groove 22, two second compression springs 24 are fixedly connected at the lower end of the supporting block 23, and an air passage 25 is arranged at the lower end of the rectangular groove 22 and positioned at the middle part of the auxiliary module 2;

wherein, the middle part upper end of air flue 25 is located sub-module 2 middle part fixed mounting and has linkage 26, and the end of air flue 25 is located sub-module 2 middle part and articulates there is lid 27, through sub-module 2 and the combined action of main module 1 for main module 1 inside cavity 5 remains in the vacuum state all the time, and material vaporization module 8 need not interrupt work in the business turn over material in-process, improves work efficiency.

Referring to fig. 5-10, linkage 26 includes two housings 2601 and two risers 2604;

wherein, a push rod 2602 is slidingly connected in the middle of the housing 2601, a tension spring 2603 is arranged in the middle of the housing 2601, and the upper ends of the two push rods 2602 are fixedly connected with a rectangular plate 2608; one end fixedly connected with third compression spring 2605 that rectangular plate 2608 was kept away from to riser 2604, riser 2604 lower extreme fixedly connected with diaphragm 2606, one side fixedly connected with fixture block 2607 that rectangular plate 2608 was close to riser 2604 upper end makes cavity 5 inside atmospheric pressure resume to standard atmospheric pressure, and the difficult gas leakage condition that takes place when cavity 5 vacuum state.

Referring to fig. 7-11, one end of the cylindrical cavity 11 away from the air passing hole 3 is communicated with the outside, and the limiting ring 12 limits the first compression spring 13, so that the cylindrical block 14 can move towards the limiting ring 12 under the action of atmospheric pressure, and the cylindrical block 14 is not easy to separate from the middle part of the cylindrical cavity 11. Track module 6, transportation rotation module 7, material vaporization module 8, light sensor 15, aspiration pump 4, pressure sensor 17 and servo motor 20 electric connection, and gear 21 and rack 19 meshing are connected for track module 6, transportation rotation module 7, material vaporization module 8, light sensor 15, aspiration pump 4, pressure sensor 17 and servo motor 20 can the linkage work, and gear 21 can drive the rack 19 motion.

Referring to fig. 2-10, rectangular protruding blocks are formed at the left and right ends of the supporting block 23, and the sealing plate 18 is located under the pressure sensor 17, so that the supporting block 23 is not easy to separate from the middle of the rectangular groove 22, and the sealing plate 18 rises to trigger the pressure sensor 17. The sealing plate 18 is larger in cross section than the cavity 5, and the sealing plate 18 is located right above the supporting blocks 23, so that the sealing plate 18 can seal the cavity 5, and the supporting blocks 23 can be pressed down by the descending of the sealing plate 18. The through hole has been seted up at air flue 25 middle part upper end in sub-module 2 middle part, and rectangular plate 2608 and through-hole assorted for air flue 25 can be linked together with sub-module 2 middle part cavity 5, and rectangular plate 2608 can plug up the through-hole.

Referring to fig. 6-13, the cover plate 27 can rotate towards the inner side of the air channel 25, and the cover plate 27 can block the air channel 25, so that the cover plate 27 is not easy to block external air from entering the air channel 25, and the air in the middle of the air channel 25 is not easy to enter the external environment from the end. The shape of the upper end of the clamping block 2607 is arc-shaped, and the lower end of the clamping block 2607 limits the rectangular plate 2608, so that the clamping block 2607 is not easy to block the rectangular plate 2608 from moving downwards, and the clamping block 2607 can limit the rectangular plate 2608 from moving upwards.

During operation, the air pump 4 at the upper end of the main module 1 pumps air in the cavity 5 through the air passing holes 3, and the cavity 5 in the middle of the main module 1 forms a vacuum environment.

The right-end auxiliary module starts feeding operation, a sealing cover 10 at the right end of the right-end auxiliary module 2 is opened, a hanging material module 9 which is already hung with materials is clamped between two transporting and rotating modules 7, then a track module 6 transports the hanging material module 9 into a cavity 5 through the transporting and rotating modules 7, the sealing cover 10 is closed, an air pump 4 at the upper end of the right-end auxiliary module 2 pumps air out the cavity 5 through an air passing hole 3, and as negative pressure is formed in the cavity 5, the air passing hole 3 and a cylindrical cavity 11, the cylindrical block 14 moves to one side of a light sensor 15, when the cavity 5, the air passing hole 3 and the cylindrical cavity 11 reach a true idle state, the cylindrical block 14 moves between the two light sensors 15, light between the two light sensors 15 is blocked, an electric signal is emitted by the light sensors 15 to control the air pump 4 to not work any more, meanwhile, a servo motor 20 controls a gear 21 to rotate, and the gear 21 drives a sealing plate 18 to move upwards through a rack 19;

when the sealing plate 18 moves upwards, the supporting block 23 moves upwards under the action of the second compression spring 24, negative pressure is formed in the rectangular groove 22 and the air passage 25, the cover disc 27 is pushed by air pressure to rotate, air enters the air passage 25, and then the cover disc 27 is reset under the action of gravity;

when the sealing plate 18 moves upwards to touch the pressure sensor 17, the pressure sensor 17 sends out an electric signal to control the servo motor 20 to stop rotating, then the pressure sensor 17 sends out an electric signal to control the track module 6 to transfer the transportation rotating module 7 and the hanging material module 9 into the cavity 5 in the middle of the main module 1, then the pressure sensor 17 controls the servo motor 20 to rotate reversely, and the servo motor 20 controls the sealing plate 18 to move downwards through the gear 21;

the closing plate 18 moves downwards to press down the support block 23, simultaneously the closing plate 18 seals the cavity 5, the support block 23 extrudes the gas in the air flue 25, because the end part of the air flue 25 is sealed by the cover plate 27, the gas moves towards the middle through hole of the air flue 25, the gas pushes the transverse plate 2606 to move towards two sides, the transverse plate 2606 drives the clamping block 2607 to move towards two sides through the vertical plate 2604, the clamping block 2607 does not limit the rectangular plate 2608 any more, under the action of air pressure, the gas pushes the cover plate 27 into the air flue 25, the gas pushes the rectangular plate 2608 to move upwards through the middle through hole of the air flue 25, the gas enters the middle cavity 5 of the right-end auxiliary module 2, the air pressure in the cavity 5 returns to standard air pressure, then the rectangular plate 2608 is reset downwards under the action of the stretching spring 2603, and the clamping block 2607 resets to limit the rectangular plate 2608 under the action of the third compression spring 2605.

The material vaporization module 8 vaporizes the material, the transportation rotation module 7 rotates the material hanging module 9, and the vacuum coating operation of the material is completed;

in the material vacuum coating process, the right side auxiliary module 2 starts to perform the feeding operation of the next hanging module 9, and the left side auxiliary module 2 starts to perform the vacuumizing operation of the cavity 5;

after the material film plating is completed, the left cavity 5 reaches a vacuum environment, after the sealing plate 18 moves upwards to touch the pressure sensor 17 at the left end, the conveying rotation module 7 conveys the hanging material module 9 completed by the vacuum film plating into the cavity 5 at the middle part of the left auxiliary module 2, then the sealing plate 18 descends to seal the cavity 5, the cavity 5 at the middle part of the left auxiliary module 2 repeats the operation so that the internal air pressure returns to the standard air pressure, and then the discharging operation of the left auxiliary module 2 is started.

In the feeding and discharging processes of the operation, the middle cavity 5 of the main module 1 is always kept in a vacuum state, and time is not required to be spent in the feeding and discharging processes so that the middle cavity 5 of the main module 1 returns to a standard air pressure state or is in a re-vacuumizing state. The combined action of the auxiliary module 2 and the main module 1 can be realized, so that the cavity 5 in the main module 1 is always kept in a vacuum state, the material vaporization module 8 does not need to interrupt work in the feeding and discharging process, and the working efficiency is improved.

The above description is only of the preferred embodiments of the present invention; the scope of the invention is not limited in this respect. Any person skilled in the art, within the technical scope of the present disclosure, may apply to the present invention, and the technical solution and the improvement thereof are all covered by the protection scope of the present invention.

Claims (9)

1. The coating device for the aluminum alloy surface comprises a main module (1), wherein the left end and the right end of the main module (1) are fixedly connected with auxiliary modules (2);

the device comprises a main module (1), a secondary module (2), a gas passing hole (3), a cavity (5) and a track module (6), wherein the middle parts of the main module (1) and the secondary module (2) are respectively provided with the gas passing hole, the upper end of the gas passing hole (3) is respectively provided with a suction pump (4), and the middle part of the track module (6) is slidably connected with a transportation rotation module (7);

the middle part of the main module (1) is provided with a material vaporization module (8), and the middle part of the transportation rotation module (7) is clamped with a material hanging module (9);

the method is characterized in that: the sealing structure is characterized in that a sealing cover (10) is hinged to the outer side of a cavity (5) formed in the auxiliary module (2), a cylindrical cavity (11) is formed in the side edge of a gas passing hole (3) formed in the auxiliary module (2), a limiting ring (12) is fixedly connected to the middle of the cylindrical cavity (11), a first compression spring (13) is placed in the middle of the cylindrical cavity (11), a cylindrical block (14) is slidably connected to the middle of the cylindrical cavity (11), light sensors (15) are fixedly connected to the upper end and the lower end of the cylindrical cavity (11), and a frame (16) is fixedly connected to one end, close to the main module (1), of the auxiliary module (2);

the device comprises a frame (16), wherein a pressure sensor (17) is fixedly connected to the upper end of the middle of the frame (16), a sealing plate (18) is slidably connected to the middle of the frame (16), racks (19) are arranged at the edges of the sealing plate (18), servo motors (20) are arranged in the middle of the left end and the right end of the frame (16), gears (21) are fixedly connected to the output ends of the servo motors (20), rectangular grooves (22) are formed in the middle of the lower end of the frame (16), supporting blocks (23) are slidably connected to the middle of the rectangular grooves (22), two second compression springs (24) are fixedly connected to the lower ends of the supporting blocks (23), and air passages (25) are formed in the middle of the auxiliary modules (2) at the lower ends of the rectangular grooves (22).

The upper end of the middle of the air passage (25) is positioned in the middle of the auxiliary module (2) and is fixedly provided with a linkage device (26), and the tail end of the air passage (25) is positioned in the middle of the auxiliary module (2) and is hinged with a cover disc (27).

2. The coating device for an aluminum alloy surface according to claim 1, wherein: the linkage (26) comprises two shells (2601) and two risers (2604);

the middle part of the shell (2601) is connected with push rods (2602) in a sliding mode, extension springs (2603) are arranged in the middle of the shell (2601), and rectangular plates (2608) are connected to the upper ends of the two push rods (2602);

wherein, one end fixedly connected with third compression spring (2605) that rectangular board (2608) was kept away from to riser (2604), riser (2604) lower extreme fixedly connected with diaphragm (2606), one side fixedly connected with fixture block (2607) that rectangular board (2608) are close to riser (2604) upper end.

3. The coating device for an aluminum alloy surface according to claim 1, wherein: one end of the cylindrical cavity (11) far away from the air passing hole (3) is communicated with the outside, and the limiting ring (12) limits the first compression spring (13).

4. The coating device for an aluminum alloy surface according to claim 1, wherein: the device comprises a track module (6), a transportation rotation module (7), a material vaporization module (8), a light sensor (15), an air pump (4), a pressure sensor (17) and a servo motor (20), wherein the track module is electrically connected, and a gear (21) is in meshed connection with a rack (19).

5. The coating device for an aluminum alloy surface according to claim 1, wherein: rectangular protruding blocks are arranged at the left end and the right end of the supporting block (23), and the sealing plate (18) is located under the pressure sensor (17).

6. The coating device for an aluminum alloy surface according to claim 1, wherein: the cross section of the sealing plate (18) is larger than that of the cavity (5), and the sealing plate (18) is positioned right above the supporting block (23).

7. The coating device for an aluminum alloy surface according to claim 2, wherein: the upper end of the middle part of the air channel (25) is positioned in the middle of the auxiliary module (2) and is provided with a through hole, and the rectangular plate (2608) is matched with the through hole.

8. The coating device for an aluminum alloy surface according to claim 1, wherein: the cover plate (27) can rotate towards the inner side of the air passage (25), and the cover plate (27) can block the air passage (25).

9. The coating device for an aluminum alloy surface according to claim 2, wherein: the upper end of the clamping block (2607) is arc-shaped, and the lower end of the clamping block (2607) limits the rectangular plate (2608).