Vacuum evaporation apparatus
By employing a wave-shaped stirring rod and filter plate, an arc-shaped stirring rod, and a multi-stage filtration structure in the vacuum evaporation device, the problem of uneven mixing of the evaporation material was solved, thereby improving the quality and effect of evaporation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SUZHOU YIKAIXUAN ELECTRONICS TECH CO LTD
- Filing Date
- 2023-06-28
- Publication Date
- 2026-07-03
Smart Images

Figure CN116791039B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of vacuum evaporation technology, and more particularly to a vacuum evaporation apparatus. Background Technology
[0002] In a vacuum deposition apparatus, sheet-like substrates are continuously fed from the feed rollers of a substrate feeding device within a vacuum chamber (main chamber) capable of creating a vacuum atmosphere. These substrates are wound onto cooling rollers, and deposition materials are deposited onto these rollers by deposition units spaced at predetermined intervals along their radial direction. The deposited sheet-like substrates are then wound up by the take-up rollers of the substrate feeding device. The vacuum chamber is divided into two chambers by partitions surrounding the rollers. The substrate feeding device is located in one chamber (deposition chamber), and deposition units are located in the other chamber (adjacent chamber). The deposition material contained in the crucible is sublimated or vaporized by heating, causing the sublimated or vaporized deposition particles to adhere and accumulate on portions of the sheet-like substrate wound on the rollers, where they are deposited (film formed).
[0003] A search revealed that Chinese patent CN112368413B discloses a "vacuum evaporation deposition apparatus," which ensures atmosphere separation between the evaporation deposition chamber equipped with the evaporation deposition unit and the adjacent main chamber when evaporating a portion of a sheet-like substrate wound on a roller. It comprises: a main chamber (1) having a substrate traveling device and a roller (2); and an evaporation deposition unit (Vu) for evaporating a portion of the sheet-like substrate (Sw) wound on the roller. The main chamber also has a first partition wall (75) and a second partition wall (7a, 7b). The first partition wall (75) divides the vapor deposition chamber into which the vapor deposition unit is housed. The second partition wall (7a, 7b) is connected to the first partition wall and is separated by a first gap (Gp1) with the curvature described above, covering the outer cylinder portion of the roller located on both sides of the circumferential side of the vapor deposition unit. The vapor deposition chamber (Vs) and the adjacent chamber (As) in the main chamber adjacent to the vapor deposition chamber are connected to each other by the first gap. The second partition wall determines the electrical conductivity between the vapor deposition chamber and the adjacent chamber.
[0004] However, when the above-mentioned material is sublimated or vaporized, it is not mixed evenly, and the sublimated or vaporized particles cannot be evenly piled on the roll, resulting in poor quality and effect of vaporization and reducing the vaporization effect of the vaporization device. Summary of the Invention
[0005] The purpose of this invention is to provide a vacuum evaporation deposition equipment that can uniformly mix the evaporation material multiple times and filter it multiple times, effectively improving the mixing effect of the evaporation material and the consistency of the evaporation particles, thereby improving the evaporation deposition quality of the device.
[0006] To achieve the above objectives, the technical solution adopted by the present invention is as follows: a vacuum evaporation deposition equipment, comprising: a base plate, an evaporation deposition chamber disposed above the base plate, a vaporization tank containing a vaporization substance fixedly installed on the top of the evaporation deposition chamber, a purification chamber and a gas pump disposed between the vaporization tank and the evaporation deposition chamber, the purification chamber and the vaporization tank being connected by a first conduit, the purification chamber and the inlet end of the gas pump being connected by a second conduit, the outlet end of the gas pump being connected to the evaporation deposition chamber by a third conduit, a support rod being disposed at each of the four corners of the top outer wall of the base plate, and a support plate being disposed between the outer walls of the four support rods, the evaporation deposition chamber being fixedly installed on the top of the support plate;
[0007] A second rotating rod is rotatably installed inside the gasification tank. Several wave-shaped second stirring rods are arranged on the outer wall of the second rotating rod along its length. The several second stirring rods are staggered and arranged in a staggered manner. A connecting rod with stirring needles and stirring columns is provided at the end of the second stirring rod. The stirring columns are located at the center of the end of the connecting rod. The stirring needles are distributed in a ring at equal intervals with the stirring columns as the center. A filter plate with several filter holes is elastically installed inside the gasification tank and above the second rotating rod.
[0008] A third rotating rod is rotatably installed on one side inside the purification box. The outer wall of the third rotating rod is provided with several arc-shaped third stirring rods. The third stirring rods are evenly spaced and the outer walls of the third stirring rods are provided with stirring blocks and stirring plates with wavy structures. The stirring blocks and stirring plates are both inclined.
[0009] On the other side inside the purification chamber and perpendicular to the third rotating rod, there is a connecting shaft with several rotating plates. The rotating plates, which are evenly distributed, are movably connected to the outer wall of the connecting shaft.
[0010] The following are further improvements to the above technical solution:
[0011] 1. In the above scheme, an arc-shaped plate with a first ventilation slot at the bottom and a second ventilation slot at the top is provided at intervals inside the purification box. An activated carbon adsorption layer, a fine filter screen and a coarse filter screen are provided between the partition plate and the arc-shaped plate, and the activated carbon adsorption layer, the fine filter screen and the coarse filter screen are distributed in sequence from top to bottom.
[0012] 2. In the above scheme, a ventilation frame is provided above the activated carbon adsorption layer, and the interior of the ventilation frame is filled with several volcanic rocks.
[0013] 3. In the above scheme, a spring is provided between each of the four corners of the filter plate and the inner wall of the gasification tank.
[0014] 4. In the above scheme, a third motor is provided on the outer wall of the purification box, and the output shaft of the third motor is connected to the third rotating rod through a coupling.
[0015] 5. In the above scheme, a horizontal plate is provided between the tops of the two support rods located on the same side, a fixing rod is installed on the top of one of the horizontal plates, and the air pump is installed on the top of the other horizontal plate.
[0016] 6. In the above scheme, a motor frame with a second motor installed on the inner wall of one side of the gasification tank is provided. This motor frame is fixedly connected to the fixed rod, and the output end of the second motor is connected to the second rotating rod through a coupling.
[0017] 7. In the above scheme, the top inner wall of the vapor deposition box is provided with a first vapor deposition plate and a second vapor deposition plate, and the first vapor deposition plate and the second vapor deposition plate are tilted in opposite directions.
[0018] 8. In the above scheme, the inner wall of the vapor deposition box is provided with second transmission rollers that are staggered vertically, and the outer wall of one side of the support rod is movably connected to the first transmission roller.
[0019] Due to the application of the above technical solution, the present invention has the following advantages compared with the prior art:
[0020] 1. The vacuum evaporation equipment of the present invention has a second rotating rod with several wave-shaped second stirring rods, which are staggered and arranged in a staggered manner. Each stirring rod has a connecting rod with stirring needles and stirring columns at its end. The stirring needles are distributed in a ring at equal intervals around the stirring columns. Inside the vaporization tank and above the second rotating rod, a filter plate with several filter holes is elastically installed. The rotation of the second stirring rod generates a large vortex, which facilitates uniform mixing of the vapor-deposited material. The filter plate can filter agglomerated vapor-deposited material, improving the uniformity of the vapor-deposited particles. Simultaneously, the filter plate is elastically connected to the inner wall of the main body. The vortex drives the filter plate to vibrate elastically, greatly reducing filter plate clogging and thus improving the adhesion of the vapor-deposited material. The uniformity is further enhanced by the fact that the third stirring rod, which has an arc-shaped structure, is equidistantly distributed on the outer wall of the third rotating rod. The outer wall of the third stirring rod is provided with stirring blocks and stirring plates with a wave-shaped structure. The stirring blocks and stirring plates are inclined. On the other side of the purification chamber and perpendicular to the third rotating rod, there is a connecting shaft with several rotating plates. The rotating plates, which are equidistantly distributed, are movably connected to the outer wall of the connecting shaft. Based on the mixing and filtration of the vaporized material in the vaporization tube, the third rotating rod rotates, thereby driving the third stirring rod, stirring blocks and stirring plates to rotate, and the vaporized material is mixed uniformly again. The stirring blocks and stirring plates are inclined and have different shapes, which can generate vortices of different sizes and angles, further improving the mixing effect of the vaporized material.
[0021] 2. The vacuum evaporation equipment of the present invention has a purification chamber with an internal partition plate having a first ventilation slot at the bottom and an arc-shaped plate having a second ventilation slot at the top. An activated carbon adsorption layer, a fine filter screen, and a coarse filter screen are arranged between the partition plate and the arc-shaped plate, and the activated carbon adsorption layer, the fine filter screen, and the coarse filter screen are distributed sequentially from top to bottom. By setting up the activated carbon adsorption layer, the fine filter screen, and the coarse filter screen, the sublimated and vaporized evaporation material is effectively filtered and adsorbed through the coarse filter screen, the fine filter screen, and the activated carbon adsorption layer, which improves the filtration effect, greatly reduces the impurity content in the evaporation material, and improves the quality of the evaporation material. Attached Figure Description
[0022] Appendix Figure 1 This is a schematic diagram of the overall structure of the vacuum evaporation equipment of the present invention;
[0023] Appendix Figure 2 This is a schematic diagram of the internal structure of the vacuum evaporation equipment of the present invention;
[0024] Appendix Figure 3 This is a schematic diagram of the internal structure of the vaporization tank in the vacuum evaporation equipment of the present invention;
[0025] Appendix Figure 4 This is a partial structural diagram of the vaporization tank in the vacuum evaporation equipment of the present invention;
[0026] Appendix Figure 5 This is a schematic diagram of the filter plate in the vacuum evaporation equipment of the present invention;
[0027] Appendix Figure 6 This is a schematic diagram of the internal structure of the purification chamber in the vacuum evaporation equipment of the present invention;
[0028] Appendix Figure 7 Appendix to this invention Figure 6 Enlarged view of point A;
[0029] Appendix Figure 8 This is a partial structural diagram of the purification chamber in the vacuum evaporation equipment of the present invention;
[0030] Appendix Figure 9 This is a partial structural cross-sectional view of the purification chamber in the vacuum evaporation equipment of the present invention.
[0031] In the attached diagrams: 1. Base plate; 2. First motor; 3. Support plate; 4. Support rod; 5. Take-up roller; 7. Horizontal plate; 8. Fixing rod; 9. Motor frame; 10. Second motor; 11. Gasification tank; 12. Shock-absorbing shell; 13. First conduit; 14. Purification box; 15. Second conduit; 16. Third conduit; 17. Air pump; 18. Evaporation box; 19. First evaporation tray; 20. Second evaporation tray; 21. First drive roller; 22. Second drive roller; 23. Filter plate; 24. Second rotating rod; 25. ... 26. Stirring rod; 27. Stirring needle; 28. Stirring tank; 29. Connecting rod; 30. Stirring column; 31. Filter hole; 32. Spring; 33. Third motor; 34. Partition plate; 35. Connecting shaft; 36. Activated carbon adsorption layer; 37. Fine filter screen; 38. Coarse filter screen; 39. Arc plate; 40. Weight reduction tank; 41. Third rotating rod; 42. Rotating plate; 43. Stirring block; 44. Third stirring rod; 45. Stirring plate; 46. First ventilation slot; 47. Ventilation frame; 48. Volcanic rock; 49. Second ventilation slot. Detailed Implementation
[0032] The present patent can be further understood through the specific embodiments given below, but they are not intended to limit the present patent.
[0033] Example 1: A vacuum evaporation equipment includes: a base plate 1, an evaporation chamber 18 disposed above the base plate 1, a vaporization tank 11 containing a vaporization substance fixedly installed on the top of the evaporation chamber 18, a purification tank 14 and a gas pump 17 disposed between the vaporization tank 11 and the evaporation chamber 18, the purification tank 14 and the vaporization tank 11 being connected by a first conduit 13, the purification tank 14 and the air inlet of the gas pump 17 being connected by a second conduit 15, the air outlet of the gas pump 17 and the evaporation chamber 18 being connected by a third conduit 16, a support rod 4 being disposed at each of the four corners of the top outer wall of the base plate 1, and a support plate 3 being disposed between the outer walls of the four support rods 4, the evaporation chamber 18 being fixedly installed on the top of the support plate 3;
[0034] Connect the equipment to the power supply and turn on the first motor. The first motor drives the first rotating rod to rotate, which in turn drives the take-up roller to rotate and drive the film to travel. The speed of the film can be adjusted by adjusting the speed of the first motor. By setting the tilt directions of the first and second vapor deposition plates to opposite directions, the film can be quickly and evenly vapor-deposited on the outer wall of the film through the second rotating roller, thereby improving the vapor deposition effect.
[0035] A second rotating rod 24 is rotatably installed inside the gasification tank 11. Several wave-shaped second stirring rods 25 are arranged on the outer wall of the second rotating rod 24 along its length. The several second stirring rods 25 are staggered and arranged in a staggered manner. A connecting rod 28 with stirring needles 26 and stirring columns 29 is provided at the end of the second stirring rod 25. The stirring columns 29 are located at the center of the end of the connecting rod 28. The stirring needles 26 are arranged in a ring with the stirring columns 29 as the center. A filter plate 23 with several filter holes 30 is elastically installed inside the gasification tank 11 and above the second rotating rod 24.
[0036] Turn on the second motor, which drives the second rotating rod to rotate, and then the second stirring rod starts to rotate. The interleaved second stirring rod and stirring needle can fully mix the vaporized material when rotating, and can effectively and evenly export the sublimated or vaporized vaporized particles. By turning on the air pump, the gas of the vaporized or sublimated vaporized material can be quickly introduced into the purification box and the vaporization box.
[0037] A third rotating rod 40 is rotatably installed on one side inside the purification box 14. The outer wall of the third rotating rod 40 is provided with a plurality of arc-shaped third stirring rods 43. The third stirring rods 43 are evenly spaced, and the outer wall of the third stirring rods 43 is provided with stirring blocks 42 and stirring plates 44 with wave-shaped structures. The stirring blocks 42 and stirring plates 44 are both inclined.
[0038] On the other side inside the purification box 14 and perpendicular to the third rotating rod 40, there is a connecting shaft 34 with several rotating plates 41. The rotating plates 41, which are evenly distributed, are movably connected to the outer wall of the connecting shaft 34.
[0039] Turn on the third motor, which drives the third rotating rod to rotate. This causes the third stirring rod, stirring block, and stirring plate to all start rotating, allowing for continued uniform mixing of the vapor-deposited material.
[0040] Inside the purification box 14, there are partitions 33 with a first ventilation slot 45 at the bottom and arc-shaped plates 38 with a second ventilation slot 48 at the top. An activated carbon adsorption layer 35, a fine filter screen 36 and a coarse filter screen 37 are arranged between the partitions 33 and the arc-shaped plates 38, and the activated carbon adsorption layer 35, the fine filter screen 36 and the coarse filter screen 37 are distributed from top to bottom.
[0041] By incorporating an activated carbon adsorption layer, a fine filter, and a coarse filter, the sublimated and vaporized vaporized material is effectively filtered and adsorbed through these three filters, improving the filtration efficiency, significantly reducing the impurity content in the vaporized material, and enhancing its quality.
[0042] A spring 31 is provided between each of the four corners of the filter plate 23 and the inner wall of the gasification tank 11.
[0043] A third motor 32 is provided on the outer wall of the purification box 14, and the output shaft of the third motor 32 is connected to the third rotating rod 40 through a coupling.
[0044] A horizontal plate 7 is provided between the tops of the two support rods 4 located on the same side. A fixing rod 8 is installed on the top of one of the horizontal plates 7, and the air pump 17 is installed on the top of the other horizontal plate 7.
[0045] The outer wall of one side of the gasification tank 11 is provided with a motor frame 9, the inner wall of which is provided with a second motor 10. This motor frame 9 is fixedly connected to the fixed rod 8. The output end of the second motor 10 is connected to the second rotating rod 24 through a coupling.
[0046] The top inner wall of the above-mentioned vapor deposition box 18 is provided with a first vapor deposition plate 19 and a second vapor deposition plate 20, and the first vapor deposition plate 19 and the second vapor deposition plate 20 are tilted in opposite directions.
[0047] The other end of the third conduit 16 is connected to two fourth conduits via a three-way pipe, and the other ends of the two fourth conduits are respectively connected to one side of the inner wall of the first vapor deposition plate 19 and the second vapor deposition plate 20.
[0048] A shock-absorbing shell 12 is provided on the outer wall of the aforementioned tank 11.
[0049] Example 2: A vacuum evaporation equipment includes: a base plate 1, an evaporation chamber 18 disposed above the base plate 1, a vaporization tank 11 containing a vaporization substance fixedly installed on the top of the evaporation chamber 18, a purification tank 14 and a gas pump 17 disposed between the vaporization tank 11 and the evaporation chamber 18, the purification tank 14 and the vaporization tank 11 being connected by a first conduit 13, the purification tank 14 and the air inlet of the gas pump 17 being connected by a second conduit 15, the air outlet of the gas pump 17 and the evaporation chamber 18 being connected by a third conduit 16, a support rod 4 being disposed at each of the four corners of the top outer wall of the base plate 1, and a support plate 3 being disposed between the outer walls of the four support rods 4, the evaporation chamber 18 being fixedly installed on the top of the support plate 3;
[0050] A second rotating rod 24 is rotatably installed inside the gasification tank 11. Several wave-shaped second stirring rods 25 are arranged on the outer wall of the second rotating rod 24 along its length. The several second stirring rods 25 are staggered and arranged in a staggered manner. A connecting rod 28 with stirring needles 26 and stirring columns 29 is provided at the end of the second stirring rod 25. The stirring columns 29 are located at the center of the end of the connecting rod 28. The stirring needles 26 are arranged in a ring with the stirring columns 29 as the center. A filter plate 23 with several filter holes 30 is elastically installed inside the gasification tank 11 and above the second rotating rod 24.
[0051] The rotation of the second stirring rod generates a large vortex, which is beneficial for the uniform mixing of the vapor-deposited material. The filter plate can filter out agglomerated vapor-deposited materials, improving the consistency of vapor-deposited particles. At the same time, the filter plate is elastically connected to the inner wall of the main body. The vortex drives the filter plate to vibrate elastically, which greatly reduces the clogging of the filter plate, thereby improving the uniformity of vapor-deposited material adhesion.
[0052] A third rotating rod 40 is rotatably installed on one side inside the purification box 14. The outer wall of the third rotating rod 40 is provided with a plurality of arc-shaped third stirring rods 43. The third stirring rods 43 are evenly spaced, and the outer wall of the third stirring rods 43 is provided with stirring blocks 42 and stirring plates 44 with wave-shaped structures. The stirring blocks 42 and stirring plates 44 are both inclined.
[0053] On the other side inside the purification box 14 and perpendicular to the third rotating rod 40, there is a connecting shaft 34 with several rotating plates 41. The rotating plates 41, which are evenly distributed, are movably connected to the outer wall of the connecting shaft 34.
[0054] The third rotating rod rotates, which in turn drives the third stirring rod, stirring block and stirring plate to rotate, so as to uniformly mix the vapor-deposited material. The stirring block and stirring plate are inclined and have different shapes, which can generate vortices of different sizes and angles, effectively improving the mixing effect of the vapor-deposited material.
[0055] Inside the purification box 14, there are partitions 33 with a first ventilation slot 45 at the bottom and arc-shaped plates 38 with a second ventilation slot 48 at the top. An activated carbon adsorption layer 35, a fine filter screen 36 and a coarse filter screen 37 are arranged between the partitions 33 and the arc-shaped plates 38, and the activated carbon adsorption layer 35, the fine filter screen 36 and the coarse filter screen 37 are distributed from top to bottom.
[0056] Both the stirring block and the stirring plate are inclined and have different shapes to generate vortices of different sizes and angles, which effectively filter and adsorb the sublimated and vaporized vaporized material through a coarse filter screen, a fine filter screen, and an activated carbon adsorption layer.
[0057] A ventilation frame 46 is provided above the activated carbon adsorption layer 35, and the interior of the ventilation frame 46 is filled with several volcanic rocks 47.
[0058] The filtration effect of vapor-deposited particles is further improved by incorporating a ventilation frame and volcanic rock.
[0059] A spring 31 is provided between each of the four corners of the filter plate 23 and the inner wall of the gasification tank 11.
[0060] A third motor 32 is provided on the outer wall of the purification box 14, and the output shaft of the third motor 32 is connected to the third rotating rod 40 through a coupling.
[0061] A horizontal plate 7 is provided between the tops of the two support rods 4 located on the same side. A fixing rod 8 is installed on the top of one of the horizontal plates 7, and the air pump 17 is installed on the top of the other horizontal plate 7.
[0062] The outer wall of one side of the gasification tank 11 is provided with a motor frame 9, the inner wall of which is provided with a second motor 10. This motor frame 9 is fixedly connected to the fixed rod 8. The output end of the second motor 10 is connected to the second rotating rod 24 through a coupling.
[0063] The top inner wall of the above-mentioned vapor deposition box 18 is provided with a first vapor deposition plate 19 and a second vapor deposition plate 20, and the first vapor deposition plate 19 and the second vapor deposition plate 20 are tilted in opposite directions.
[0064] The inner wall of the vapor deposition box 18 is provided with a second transmission roller 22 that is staggered vertically, and the second transmission roller 22 is used to transport the base fabric.
[0065] A first drive roller 21 is movably connected between two support rods 4 on one side, and a take-up roller 5 is movably connected between two support rods 4 on the other side.
[0066] A first motor 2 is provided on the outer wall of the support rod 4, and the output shaft of the first motor 2 is connected to a first rotating rod through a coupling. A take-up roller 5 is provided on the outer wall of the first rotating rod.
[0067] The outer wall of the second stirring rod 25 is provided with a stirring groove 27.
[0068] The outer wall of the aforementioned rotating plate 41 is provided with a weight-reducing groove 39.
[0069] The working principle is as follows:
[0070] When in use, connect the equipment to the power supply and turn on the first motor. The first motor drives the first rotating rod to rotate, which in turn drives the take-up roller to rotate and drive the film to travel. The speed of the film can be adjusted by adjusting the speed of the first motor. By setting the tilt direction of the first and second vapor deposition plates to opposite directions, the film can be quickly transported by the second rotating roller, which can quickly and evenly vapor deposit the outer wall of the film and improve the vapor deposition effect.
[0071] The second motor is turned on, driving the second rotating rod to rotate, which in turn causes the second stirring rod to rotate. The staggered arrangement of the second stirring rods and stirring needles during rotation ensures thorough mixing of the vapor-deposited material, effectively and evenly discharging the sublimated or vaporized vapor-deposited particles. By activating the gas pump, the vaporized or sublimated vapor-deposited material is quickly introduced into the purification chamber and the vapor deposition chamber.
[0072] The third motor is turned on, which drives the third rotating rod to rotate. This causes the third stirring rod, stirring block, and stirring plate to all start rotating, allowing for continued uniform mixing of the vapor-deposited material. The stirring block and stirring plate are inclined and have different shapes, which can generate vortices of different sizes and angles. The sublimated and vaporized vapor-deposited material is effectively filtered and adsorbed through a coarse filter, a fine filter, and an activated carbon adsorption layer. The filtration effect of the vapor-deposited particles is further improved by the addition of a ventilation frame and volcanic rock.
[0073] When using the aforementioned vacuum evaporation equipment, the rotation of the second stirring rod generates a large vortex, which is beneficial for the uniform mixing of the evaporation material. Furthermore, the filter plate can filter out agglomerated evaporation materials, improving the consistency of the evaporation particles. Simultaneously, the filter plate is elastically connected to the inner wall of the main body, and the vortex drives the filter plate to vibrate elastically, greatly reducing filter plate clogging and thus improving the uniformity of the evaporation material adhesion. Further, based on the mixing and filtering of the evaporation material in the vaporization tube, the rotation of the third rotating rod drives the third stirring rod, stirring block, and stirring plate to rotate again, uniformly mixing the evaporation material once more. The stirring block and stirring plate are both inclined and have different shapes, generating vortices of different sizes and angles, further improving the mixing effect of the evaporation material.
[0074] Furthermore, the interior of its purification chamber is equipped with a partition with ventilation slots at the bottom. Above the ventilation slots, between the partition and the arc-shaped plate, are an activated carbon adsorption layer, a fine filter, and a coarse filter, arranged sequentially from top to bottom. By incorporating these elements, the sublimated and vaporized vaporized material is effectively filtered and adsorbed through the coarse and fine filters and the activated carbon adsorption layer, improving the filtration effect, significantly reducing the impurity content in the vaporized material, and enhancing its quality.
[0075] The above embodiments are only for illustrating the technical concept and features of the present invention, and are intended to enable those skilled in the art to understand the content of the present invention and implement it accordingly. They should not be construed as limiting the scope of protection of the present invention. All equivalent changes or modifications made in accordance with the spirit and essence of the present invention should be covered within the scope of protection of the present invention.
Claims
1. A vacuum evaporation deposition apparatus, comprising: The base plate (1) is characterized in that: a vapor deposition box (18) is provided above the base plate (1), and a vaporization tank (11) containing vapor deposition material is fixedly installed on the top of the vapor deposition box (18). A purification box (14) and a gas pump (17) are provided between the vaporization tank (11) and the vapor deposition box (18). The purification box (14) and the vaporization tank (11) are connected by a first conduit (13). The purification box (14) and the air inlet of the gas pump (17) are connected by a second conduit (15). The air outlet of the gas pump (17) and the vapor deposition box (18) are connected by a third conduit (16). A support rod (4) is provided at each of the four corners of the top outer wall of the base plate (1), and a support plate (3) is provided between the outer walls of the four support rods (4). The vapor deposition box (18) is fixedly installed on the top of the support plate (3). A second rotating rod (24) is rotatably installed inside the gasification tank (11). Several second stirring rods (25) with a wave-shaped structure are arranged on the outer wall of the second rotating rod (24) along its length. The several second stirring rods (25) are staggered and arranged in a staggered manner. A connecting rod (28) with stirring needles (26) and stirring columns (29) is provided at the end of the second stirring rod (25). The stirring columns (29) are located at the center of the end of the connecting rod (28). The stirring needles (26) are arranged in a ring with the stirring columns (29) as the center. A filter plate (23) with several filter holes (30) is elastically installed inside the gasification tank (11) and above the second rotating rod (24). A third rotating rod (40) is rotatably installed on one side inside the purification box (14). The outer wall of the third rotating rod (40) is provided with a number of arc-shaped third stirring rods (43). The third stirring rods (43) are distributed at equal intervals, and the outer wall of the third stirring rods (43) is provided with stirring blocks (42) and stirring plates (44) with wave-shaped structures. The stirring blocks (42) and stirring plates (44) are both inclined. On the other side of the interior of the purification box (14) and perpendicular to the third rotating rod (40), there is a connecting shaft (34) with several rotating plates (41). The rotating plates (41) distributed at equal intervals are movably connected to the outer wall of the connecting shaft (34). Inside the purification box (14), there are partitions (33) with a first ventilation groove (45) at the bottom and arc-shaped plates (38) with a second ventilation groove (48) at the top. An activated carbon adsorption layer (35), a fine filter (36) and a coarse filter (37) are arranged between the partition (33) and the arc-shaped plate (38), and the activated carbon adsorption layer (35), the fine filter (36) and the coarse filter (37) are distributed from top to bottom. The top inner wall of the vapor deposition box (18) is provided with a first vapor deposition plate (19) and a second vapor deposition plate (20) opposite to each other, and the first vapor deposition plate (19) and the second vapor deposition plate (20) are inclined in opposite directions; the inner wall of the vapor deposition box (18) is provided with a second transmission roller (22) that is staggered vertically.
2. The vacuum evaporation equipment according to claim 1, characterized in that: A ventilation frame (46) is provided above the activated carbon adsorption layer (35), and the interior of the ventilation frame (46) is filled with several volcanic rocks (47).
3. The vacuum evaporation equipment according to claim 1, characterized in that: A spring (31) is provided between each of the four corners of the filter plate (23) and the inner wall of the gasification tank (11).
4. The vacuum evaporation equipment according to claim 1, characterized in that: A third motor (32) is provided on the outer wall of the purification box (14), and the output shaft of the third motor (32) is connected to the third rotating rod (40) through a coupling.
5. The vacuum evaporation equipment according to claim 1, characterized in that: A horizontal plate (7) is provided between the tops of the two support rods (4) located on the same side, with a fixing rod (8) installed on the top of one of the horizontal plates (7) and the air pump (17) installed on the top of the other horizontal plate (7).
6. The vacuum evaporation equipment according to claim 1, characterized in that: The outer wall of one side of the gasification tank (11) is provided with a motor frame (9) with a second motor (10) on the inner wall. The motor frame (9) is fixedly connected to the fixed rod (8). The output end of the second motor (10) is connected to the second rotating rod (24) through a coupling.