A flexible curtain wall coating material production equipment and a method of using the same

Abstract

A kind of flexible curtain coating material production equipment, including bottom plate, the bottom plate upper end is equipped with stirring barrel, stirring barrel upper end is equipped with rotatable first rotation axis, first rotation axis lower end is equipped with scraper matched with stirring barrel inner wall, when the first rotation axis rotates, it can constitute the structure that scraper rotates along stirring barrel inner wall circumference and then moves to outside again and then moves downward;Stirring barrel lower end is equipped with loading cylinder, loading cylinder lower end is equipped with sealing cover, loading cylinder rear side is equipped with rotatable second rotation axis, the bottom plate upper end is also equipped with multiple receiving cylinders, when the second rotation axis rotates, it can constitute the structure that sealing cover is intermittently turned over downward, receiving cylinder is intermittently moved synchronously;It can clean equipment inner wall in time when producing, prevent coating from adhering to equipment inner wall to cause certain waste, and also can automatically batch production packing, reduce the labor of worker, improve production efficiency.

Description

Technical Field

[0001] This invention relates to the field of curtain wall coating material production technology, and in particular to a flexible curtain wall coating material production equipment and its usage method. Background Technology

[0002] A curtain wall is a non-load-bearing enclosure structure that hangs on the exterior wall of a building, like a curtain. It does not serve as part of the main structure or bear any load. Generally, curtain walls are lightweight, strong, and aesthetically pleasing, thus providing a decorative function for architecture. Flexible curtain walls also have many advantages, such as good air permeability, excellent fire resistance, environmental friendliness, strong wind and pressure resistance, rainwater leakage prevention, high energy efficiency, strong in-plane deformation and seismic resistance, and good thermal insulation. Flexible curtain wall coating materials, including rutile titanium dioxide, precipitated barium sulfate, propylene glycol, dispersants, multifunctional additives, defoamers, and rheology modifiers, are diverse and mostly composed of multiple substances mixed together. Due to the viscosity of the coating, it often adheres to the inner wall of the equipment during production, leading to waste and affecting production efficiency. Furthermore, existing equipment cannot automatically produce in batches. Therefore, a flexible curtain wall coating material production equipment is designed to solve the problems mentioned above. Summary of the Invention

[0003] This invention addresses the shortcomings of existing technologies by providing a flexible curtain wall coating material production equipment. This equipment can clean the inner wall of the equipment in a timely manner during production, preventing coating from adhering to the inner wall and causing waste. Furthermore, it can automatically produce and package in batches, reducing the workload of workers, improving production efficiency, and effectively solving the problems mentioned in the background section.

[0004] The technical solution adopted by the present invention to solve the above problems is as follows:

[0005] A flexible curtain wall coating material production equipment includes a base plate, a mixing tank at the upper end of the base plate, a rotatable first rotating shaft at the upper end of the mixing tank, and a scraper at the lower end of the first rotating shaft that cooperates with the inner wall of the mixing tank. When the first rotating shaft rotates, the scraper can rotate circumferentially along the inner wall of the mixing tank and move outward and then downward. A loading cylinder is provided at the lower end of the mixing tank, and a sealing cover is provided at the lower end of the loading cylinder. A rotatable second rotating shaft is provided at the rear side of the loading cylinder. A plurality of receiving cylinders are also provided at the upper end of the base plate. When the second rotating shaft rotates, the sealing cover can be intermittently flipped downward and the receiving cylinders can be intermittently moved synchronously.

[0006] A support arm is fixedly connected to the rear side of the upper surface of the base plate. A first motor is fixedly connected to the upper end of the support arm. A first rotating shaft is fixedly connected to the lower end of the first motor. A spur gear is fixedly connected to the outer surface of the first rotating shaft. A planetary spur gear meshes with the outer surface of the spur gear. An internal gear ring is fixedly connected to the inner wall of the upper end of the mixing tank. The planetary spur gear meshes with the inner wall of the internal gear ring. A first support plate is provided at the lower end of the spur gear. The planetary spur gear is rotatably connected to the first support plate. The scraper is installed on one side of the lower end of the first support plate.

[0007] A crank is fixedly connected to the lower end of the outer surface of the first rotating shaft, and a rocker arm is hinged to the other end of the crank. A stirring shaft is slidably connected to the inner wall of the first support plate. The other end of the rocker arm is rotatably connected to the stirring shaft. A small spur gear is fixedly connected to the upper end of the outer surface of the stirring shaft. A spur rack that meshes with the small spur gear is fixedly connected to the lower surface of the first support plate. Multiple stirring rods are fixedly connected to the outer surface of the stirring shaft.

[0008] The lower end of the planetary spur gear is coaxially fixed to a planar cam, and the lower surface of the planar cam is engaged with a second sliding pin. The lower surface of the first support plate is fixed to an L-shaped support seat, and the second sliding pin is slidably connected to the inner wall of the L-shaped support seat. The lower surface of the first support plate is also slidably connected to a multi-stage telescopic rod. The scraper is fixed to the lower surface of the multi-stage telescopic rod. The lower end of the outer surface of the second sliding pin is fixed to a push rod, and the other end of the push rod is fixed to the multi-stage telescopic rod.

[0009] A cylindrical cam is coaxially fixed to the upper end of the planetary spur gear. A first sliding pin meshes with the outer surface of the cylindrical cam. An L-shaped connecting rod extending downward is fixed to the outer surface of the first sliding pin. A limit block is fixed to the rear end surface of the first support plate. The L-shaped connecting rod is slidably connected to the inner wall of the limit block. An extension plate is provided at the front end of the scraper. The L-shaped connecting rod is slidably connected to the extension rod.

[0010] A second motor is fixed to the upper surface of the base plate, a driving bevel gear is fixed to the front end of the second motor, a driven bevel gear meshes with the front end of the driving bevel gear, a second rotating shaft is fixed to the inner wall of the driven bevel gear, a shaped cam is provided on the upper end of the outer surface of the second rotating shaft, the sealing cover is hinged to the lower surface of the loading cylinder, and an extension rod that cooperates with the shaped cam is also provided on the rear side of the sealing cover.

[0011] An incomplete spur gear is fixedly connected to the lower end of the outer surface of the second rotating shaft. A driven spur gear that meshes with the incomplete spur gear is rotatably connected to the upper surface of the base plate. A sector-shaped locking wheel is coaxially fixedly connected to the lower end of the incomplete spur gear. A concave locking wheel that meshes with the sector-shaped locking wheel is coaxially fixedly connected to the lower end of the driven spur gear. A driving pulley is coaxially fixedly connected to the lower end of the concave locking wheel. A driven pulley is connected to the left side of the driving pulley. A first bevel gear is coaxially fixedly connected to the upper end of the driven pulley. A second bevel gear meshes with the upper end of the first bevel gear. A main friction wheel is coaxially fixedly connected to the front end of the second bevel gear. A secondary friction wheel is rotatably connected to the upper end of the base plate. A transmission belt is fitted on the outer surface of the main friction wheel and the secondary friction wheel. The receiving cylinder is evenly placed on the conveyor belt.

[0012] A vertical plate is fixedly connected to the front side of the upper surface of the base plate. A support plate is slidably connected to the upper side of the rear surface of the vertical plate. A handle is rotatably connected to the lower side of the front surface of the support plate. A third bevel gear is coaxially fixed to the rear end of the handle. A fourth bevel gear meshes with the lower end of the third bevel gear. A threaded rod that is rotatably connected to the vertical plate is fixedly connected to the inner wall of the center of the fourth bevel gear. The support plate is threadedly connected to the outer surface of the threaded rod. The loading cylinder includes an inner cylinder and an outer cylinder. The inner cylinder is fixedly connected to the lower surface of the mixing tank. The outer cylinder is slidably connected to the lower end of the outer surface of the inner cylinder. The outer cylinder is also fixedly connected to the inner wall of the support plate. The shaped cam is rotatably connected to the inner wall of the support plate. The shaped cam is also slidably connected to the outer surface of the second rotating shaft.

[0013] A method for using a flexible curtain wall coating material production equipment includes the following steps:

[0014] After pouring the materials into the mixing tank, start the first motor. This will cause the mixing shaft to rotate, move back and forth in a circular motion, and the mixing rod can mix and stir the materials in the mixing tank over a large area.

[0015] After starting the first motor, S2 will drive the scraper to work. While rotating in a circle, the scraper can move outward and then move downward after contacting the inner wall of the mixing tank.

[0016] After the mixing is complete, the second motor is started by S3, which will pour equal amounts of material into the receiving cylinder in sequence and evenly. The amount of material poured into the receiving cylinder can be adjusted by turning the handle.

[0017] This invention features a novel structure, ingenious design, and simple and convenient operation, offering the following advantages compared to existing technologies:

[0018] 1. After pouring the materials into the mixing tank, start the first motor. This will cause the mixing shaft to rotate, move back and forth in a circular motion, and mix the materials in the mixing tank over a large area.

[0019] 2. After the first motor is started, it will drive the scraper to work. While the scraper rotates in a circle, it can also move outward and contact the inner wall of the mixing tank. Then it will move downward to scrape the material adhering to the mixing tank downward.

[0020] 3. After the mixing is complete, start the second motor, which will cause equal amounts of material to be poured into the receiving cylinder in sequence and evenly. Turning the handle can adjust the amount of material poured into the receiving cylinder. Attached Figure Description

[0021] Figure 1 This is an isometric view of a flexible curtain wall coating material production equipment according to the present invention.

[0022] Figure 2This is a cross-sectional view of the mixing tank of a flexible curtain wall coating material production equipment according to the present invention.

[0023] Figure 3 This is a schematic diagram of the internal structure of the mixing tank in a flexible curtain wall coating material production equipment according to the present invention.

[0024] Figure 4 This is a schematic diagram of the crank installation of a flexible curtain wall coating material production equipment according to the present invention.

[0025] Figure 5 This is a schematic diagram of the rocker arm installation of a flexible curtain wall coating material production equipment according to the present invention.

[0026] Figure 6 This is a schematic diagram of the installation of multi-stage telescopic rods in a flexible curtain wall coating material production equipment according to the present invention.

[0027] Figure 7 This is a cross-sectional view of an L-shaped support base for a flexible curtain wall coating material production equipment according to the present invention.

[0028] Figure 8 This is a schematic diagram of the installation of an irregularly shaped cam in a flexible curtain wall coating material production equipment according to the present invention.

[0029] Figure 9 This is a schematic diagram of the incomplete spur gear installation of a flexible curtain wall coating material production equipment according to the present invention.

[0030] Figure 10 This is a schematic diagram of the installation of a sector-shaped locking wheel in a flexible curtain wall coating material production equipment according to the present invention.

[0031] Figure 11 This is a schematic diagram of the installation of the main friction wheel in a flexible curtain wall coating material production equipment according to the present invention.

[0032] Figure 12 This is a schematic diagram of the pallet installation of a flexible curtain wall coating material production equipment according to the present invention.

[0033] Numbered components in the diagram: 1-Base plate, 2-Support column, 3-Support arm, 4-Support sleeve, 5-First motor, 6-First shaft, 7-Stellar spur gear, 8-Planetary spur gear, 9-Internal gear ring, 10-First support plate, 11-Mixing tank, 12-Crank, 13-Rock arm, 14-Mixing shaft, 15-Small spur gear, 16-Spur rack, 17-Cylindrical cam, 18-First sliding pin, 19-L-shaped connecting rod, 20-Limiting block, 21-Extension plate, 22-Scraper, 23-Multi-stage telescopic rod, 24-Plane cam, 25-L-shaped support seat, 26-Second sliding pin, 27-Push rod, 28-Second... Motor, 29-Driving bevel gear, 30-Driven bevel gear, 31-Incomplete spur gear, 32-Driven spur gear, 33-Sector lock wheel, 34-Concave lock wheel, 35-Driving pulley, 36-Driven pulley, 37-First bevel gear, 38-Second bevel gear, 39-Main friction wheel, 40-Secondary friction wheel, 41-Receiving cylinder, 42-Upright plate, 43-Handle, 44-Third bevel gear, 45-Fourth bevel gear, 46-Threaded rod, 47-Support plate, 48-Inner cylinder, 49-Outer cylinder, 50-Sealing cover, 51-Irregular cam, 52-Second rotating shaft, 53-Extension rod, 54-Loading cylinder. Detailed Implementation

[0034] The following are specific embodiments of the present invention, and the technical solutions of the present invention will be further described in conjunction with the accompanying drawings. However, the present invention is not limited to these embodiments.

[0035] like Figure 1-12 As shown, the present invention provides a flexible curtain wall coating material production equipment, including a base plate 1. A mixing tank 11 is provided at the upper end of the base plate 1. A rotatable first rotating shaft 6 is provided at the upper end of the mixing tank 11. A scraper 22 that cooperates with the inner wall of the mixing tank 11 is provided at the lower end of the first rotating shaft 6. When the first rotating shaft 6 rotates, the scraper 22 can be configured to rotate circumferentially along the inner wall of the mixing tank 11 and move outward and then downward. A loading cylinder 54 is provided at the lower end of the mixing tank 11. A sealing cover 50 is provided at the lower end of the loading cylinder 54. A rotatable second rotating shaft 52 is provided at the rear side of the loading cylinder 54. A plurality of receiving cylinders 41 are also provided at the upper end of the base plate 1. When the second rotating shaft 52 rotates, the sealing cover 50 can be configured to intermittently flip downward and the receiving cylinders 41 can be configured to intermittently move synchronously.

[0036] like Figure 1-4As shown in Figures 8 and 9, the base supports and fixes the entire device. Four evenly distributed support columns 2 are fixed to the upper surface of the base, and a support sleeve 4 is fixed to the upper surface of the four support columns 2. The mixing tank 11 is fixed to the inner wall of the support sleeve 4. The mixing tank 11 is fixed by the support columns 2 and the support sleeve 4. When the material is poured into the mixing tank 11, during production, when the first rotating shaft 6 rotates, the scraper 22 will rotate in a circular motion and move outward and downward. When the scraper 22 moves outward, it will contact the inner wall of the mixing tank 11. When it moves downward, it will scrape the material adhering to the inner wall of the mixing tank 11 downward, thereby cleaning the material. The scraper 22 can perform a large-area scanning scraping when it rotates in a circle, thus thoroughly cleaning the inner wall of the mixing tank 11 and preventing material from adhering to the inner wall of the mixing tank 11 and causing some waste. After the material in the mixing tank 11 is mixed, it will flow into the inner wall of the loading cylinder 54. When the second rotating shaft 52 rotates, the sealing cover 50 can be flipped downward intermittently, thereby opening the bottom of the loading cylinder 54 and allowing the material to flow into the corresponding receiving cylinder 41. By intermittently flipping downward of the sealing cover 50 and intermittently moving synchronously with the receiving cylinder 41, the material can be loaded into the receiving cylinder 41 in sequence, thereby completing the production of equal batches, which will not be described in detail.

[0037] A support arm 3 is fixedly connected to the rear side of the upper surface of the base plate 1. A first motor 5 is fixedly connected to the upper end of the support arm 3. A first rotating shaft 6 is fixedly connected to the lower end of the first motor 5. A spur gear 7 is fixedly connected to the outer surface of the first rotating shaft 6. A planetary spur gear 8 meshes with the outer surface of the spur gear 7. An internal gear ring 9 is fixedly connected to the inner wall of the upper end of the mixing tank 11. The planetary spur gear 8 meshes with the inner wall of the internal gear ring 9. A first support plate 10 is provided at the lower end of the spur gear 7. The planetary spur gear 8 is rotatably connected to the first support plate 10. The scraper 22 is installed on one side of the lower end of the first support plate 10.

[0038] like Figure 2-4 As shown, the support arm 3 serves to support the first motor 5 and the first rotating shaft 6; the first motor 5 provides rotational power to the first rotating shaft 6. The motor is existing technology and will not be described further; the spur gear 7, planetary spur gear 8, and internal gear ring 9 are installed and shaped as follows... Figure 3 As shown, the first support plate 10 is rotatably connected to the lower end of the outer surface of the first rotating shaft 6, which is equivalent to being rotatably connected to the spur gear 7. The planetary spur gear 8 has a rotating shaft fixed at its center, which is rotatably connected to the inner wall of the first support plate 10. When the first motor 5 is started, it will drive the first rotating shaft 6 to rotate. The rotation of the first rotating shaft 6 will drive the spur gear 7 to rotate. The rotation of the spur gear 7 will drive the planetary spur gear 8 to rotate through meshing with the planetary spur gear 8. When the planetary spur gear 8 rotates, it will drive the first support plate 10 to rotate through meshing with the internal gear ring 9. When the first support plate 10 rotates, it will drive the scraper 22 to rotate in a circular motion.

[0039] A crank 12 is fixedly connected to the lower end of the outer surface of the first rotating shaft 6, and a rocker arm 13 is hinged to the other end of the crank 12. A stirring shaft 14 is slidably connected to the inner wall of the first support plate 10. The other end of the rocker arm 13 is rotatably connected to the stirring shaft 14. A small spur gear 15 is fixedly connected to the upper end of the outer surface of the stirring shaft 14. A spur rack 16 that meshes with the small spur gear 15 is fixedly connected to the lower end surface of the first support plate 10. Multiple stirring rods are fixedly connected to the outer surface of the stirring shaft 14.

[0040] like Figure 4-5 As shown, a circular ring pad is fixed to the upper end of the outer surface of the stirring shaft 14. A keyway is provided on the inner wall of the first support plate 10, and the circular ring pad is slidably connected to the inner wall of the keyway, limiting the stirring shaft 14 to move back and forth and rotate. The stirring shaft 14 and the stirring rod are used to mix and stir the materials in the mixing tank 11. The crank 12, rocker arm 13, small spur gear 15, and spur rack 16 are installed and shaped as follows... Figure 5 As shown, when the first rotating shaft 6 rotates, it will drive the crank 12 to rotate in a circular motion. The rotation of the crank 12 will drive one end of the corresponding rocker arm 13 to rotate in a circular motion. The other end of the rocker arm 13 will pull the corresponding stirring shaft 14 to move back and forth, that is, the corresponding stirring rod and small spur gear 15 to move back and forth in a reciprocating motion. When the small spur gear 15 moves back and forth in a reciprocating motion, it will mesh with the rack 16, causing the small spur gear 15 and the stirring shaft 14 to rotate, thereby causing the stirring rod to stir the material. When the stirring shaft 14 moves back and forth in a reciprocating motion, it can increase the stirring area. When the first support plate 10 rotates in a circular motion, it can further increase the stirring range, thereby comprehensively stirring and mixing the material inside the mixing tank 11.

[0041] The lower end of the planetary spur gear 8 is coaxially fixed to a planar cam 24, and a second sliding pin 26 is engaged on the lower surface of the planar cam 24. An L-shaped support seat 25 is fixed to the lower surface of the first support plate 10, and the second sliding pin 26 is slidably connected to the inner wall of the L-shaped support seat 25. A multi-stage telescopic rod 23 is also slidably connected to the lower surface of the first support plate 10. A scraper 22 is fixed to the lower surface of the multi-stage telescopic rod 23. A push rod 27 is fixed to the lower end of the outer surface of the second sliding pin 26, and the other end of the push rod 27 is fixed to the multi-stage telescopic rod 23.

[0042] like Figure 6-7 As shown, the function of the multi-stage telescopic rod 23 is to limit the scraper 22 to move up and down only on the multi-stage telescopic rod 23. The multi-stage telescopic rod 23 is as follows: Figure 6 The prior art shown is not described in detail here. The sliding connection between the multi-stage telescopic rod 23 and the lower surface of the first support plate 10 is as follows: the planar cam 24 and the second sliding pin 26 are installed and shaped as shown in the figure. Figure 7As shown, the L-shaped support 25 limits the second sliding pin 26 to slide only back and forth. When the second sliding pin 26 is engaged with the planar cam 24, the second sliding pin 26 will intermittently move back and forth when the planar cam 24 rotates. When the planetary spur gear 8 rotates, it will drive the corresponding planar cam 24 to rotate. The rotation of the planar cam 24, through its engagement with the second sliding pin 26, will cause the second sliding pin 26 to move synchronously outward or inward. When the second sliding pin 26 moves outward, that is, moves backward, it will drive the push rod 27 and the multi-stage telescopic rod 23 to move backward. When the multi-stage telescopic rod 23 moves backward, it will drive the scraper 22 to move backward, so that the scraper 22 contacts the inner wall of the mixing tank 11. When the planar cam 24 engages with the second sliding pin 26 and causes the second sliding pin 26 to move forward, it will cause the scraper 22 to move inward, so that the scraper 22 disengages from the inner wall of the mixing tank 11.

[0043] The upper end of the planetary spur gear 8 is coaxially fixed to a cylindrical cam 17. The outer surface of the cylindrical cam 17 is engaged with a first sliding pin 18. The outer surface of the first sliding pin 18 is fixed to a downwardly extending L-shaped connecting rod 19. The rear end surface of the first support plate 10 is fixed to a limiting block 20. The L-shaped connecting rod 19 is slidably connected to the inner wall of the limiting block 20. The front end of the scraper 22 is provided with an extension plate 21. The L-shaped connecting rod 19 is slidably connected to the extension rod 53.

[0044] like Figure 6 As shown, the limiting block 20 restricts the L-shaped connecting rod 19 to move only up and down. Through the sliding connection between the extension plate 21 and the L-shaped connecting rod 19, the scraper 22 can slide forward or backward without disengaging from the L-shaped connecting rod 19. Through the multi-stage telescopic rod 23, when the L-shaped connecting rod 19 moves up and down, it can also drive the corresponding scraper 22 to move up and down. When the cylindrical cam 17 rotates, its engagement with the first sliding pin 18 causes the first sliding pin 18 and the L-shaped connecting rod 19 to move up or down. When the L-shaped connecting rod 19 moves upward, it drives the corresponding extension plate 21 and the scraper 22 to move upward synchronously. Furthermore, through the interaction of the cylindrical cam 17 and the planar cam 24, when the planar cam 24 and the cylindrical cam 17 rotate synchronously, the scraper 22 will contact the inner wall of the mixing tank 11 when it moves from top to bottom, so that the material is scraped to the lower side of the mixing tank 11. When the scraper 22 moves from bottom to top, the scraper 22 will disengage from the inner wall of the mixing tank 11 to prevent the scraper 22 from scraping back the material. Therefore, the scraper 22 will move along a trajectory similar to a parallelogram. Under the circumferential rotation of the first support plate 10, the scraper 22 will also rotate in a circle, thereby thoroughly scraping the material from the inner wall of the mixing tank 11.

[0045] A second motor 28 is fixedly connected to the upper surface of the base plate 1. A driving bevel gear 29 is fixedly connected to the front end of the second motor 28. A driven bevel gear 30 meshes with the front end of the driving bevel gear 29. A second rotating shaft 52 is fixedly connected to the inner wall of the driven bevel gear 30. A shaped cam 51 is provided on the upper end of the outer surface of the second rotating shaft 52. The sealing cover 50 is hinged to the lower surface of the loading cylinder 54. An extension rod 53 that cooperates with the shaped cam 51 is also provided on the rear side of the sealing cover 50.

[0046] like Figure 8-9 As shown in Figure 12, the function of the second motor 28 is to provide rotational power for the second rotating shaft 52. The second rotating shaft 52 is rotatably connected to the inner wall of the base. The irregular cam 51, sealing cover 50, and extension rod 53 are installed and shaped as shown in Figure 12. Figure 12 As shown, when the irregular cam 51 rotates, it will cause the sealing cover 50 to flip up and down intermittently through its cooperation with the extension rod 53. Since one end of the sealing cover 50 is heavier, it will cause the extension rod 53 to have an upward flipping force, so that the extension rod 53 and the irregular cam 51 are always in contact and meshing. When the second motor 28 is started, the corresponding active bevel gear 29 will rotate. The rotation of the active bevel gear 29 will cause the driven bevel gear 30 and the second rotating shaft 52 to rotate synchronously through meshing. When the second rotating shaft 52 rotates, it will drive the irregular cam 51 to rotate. The rotation of the irregular cam 51 and its meshing with the extension rod 53 will cause the corresponding sealing cover 50 to flip up and down intermittently, so that the material inside the loading cylinder 54 will be poured out.

[0047] An incomplete spur gear 31 is fixedly connected to the lower end of the outer surface of the second rotating shaft 52. A driven spur gear 32 that meshes with the incomplete spur gear 31 is rotatably connected to the upper surface of the base plate 1. A sector-shaped locking wheel 33 is coaxially fixedly connected to the lower end of the incomplete spur gear 31. A concave locking wheel 34 that meshes with the sector-shaped locking wheel 33 is coaxially fixedly connected to the lower end of the driven spur gear 32. A driving pulley 35 is coaxially fixedly connected to the lower end of the concave locking wheel 34. A driven pulley 36 is connected to the left side of the driving pulley 35. A first bevel gear 37 is coaxially fixedly connected to the upper end of the driven pulley 36. A second bevel gear 38 meshes with the upper end of the first bevel gear 37. A main friction wheel 39 is coaxially fixedly connected to the front end of the second bevel gear 38. A secondary friction wheel 40 is rotatably connected to the upper end of the base plate 1. A transmission belt is sleeved on the outer surface of the main friction wheel 39 and the secondary friction wheel 40. The receiving cylinder 41 is evenly placed on the conveyor belt.

[0048] like Figure 8-11 As shown, the incomplete spur gear 31 and the driven spur gear 32 are mounted and shaped as follows: Figure 9As shown, a rotating shaft is fixedly connected to the center of the driven spur gear 32, the concave locking wheel 34, and the driving pulley 35. The rotating shaft is rotatably connected to the inner wall of the base plate 1. When the incomplete spur gear 31 rotates, it can cause the driven spur gear 32 to rotate intermittently through its engagement with the driven spur gear 32. Through the meshing of the concave locking wheel 34 and the sector locking wheel 33, the incomplete spur gear 31 can disengage from the driven spur gear 32, preventing the driven spur gear 32 from rotating. A rotating shaft is fixedly connected to the center of the driven pulley 36 and the first bevel gear 37. The rotating shaft is rotatably connected to the inner wall of the base plate 1. A rotating shaft is fixedly connected to the center of the second bevel gear 38, the main friction wheel 39, and the auxiliary friction wheel 40, respectively. Bearing seats are rotatably connected to the front and rear ends of the outer surface of the rotating shaft, respectively. The bottom ends of the bearing seats are fixed to the upper surface of the base plate 1, limiting the main friction wheel 39 and the auxiliary friction wheel 40 to rotate only. When the second rotating shaft 52 rotates, it drives the incomplete spur gear 31 to rotate. The rotation of the incomplete spur gear 31, through its engagement with the driven spur gear 32, causes the driven spur gear to rotate intermittently. It also has a self-locking function under the engagement of the sector locking wheel 33 and the concave locking wheel 34. When the driven spur gear 32 rotates, through meshing, coaxial transmission and belt transmission, it causes the driving pulley 35, the first bevel gear 37, the second bevel gear 38 and the main friction wheel 39 to rotate. When the main friction wheel 39 rotates, the conveyor belt moves under the tension of the auxiliary friction wheel 40, thereby causing the corresponding receiving cylinder 41 to move intermittently.

[0049] A vertical plate 42 is fixedly connected to the front side of the upper surface of the base plate 1. A support plate 47 is slidably connected to the upper side of the rear surface of the vertical plate 42. A handle 43 is rotatably connected to the lower side of the front surface of the support plate 47 and the vertical plate 42. A third bevel gear 44 is coaxially fixedly connected to the rear end of the handle 43. A fourth bevel gear 45 meshes with the lower end of the third bevel gear 44. A threaded rod 46, which is rotatably connected to the vertical plate 42, is fixedly connected to the inner wall of the center of the fourth bevel gear 45. The support plate 47 is threadedly connected to the outer surface of the threaded rod 46. The loading cylinder 54 includes an inner cylinder 48 and an outer cylinder 49. The inner cylinder 48 is fixedly connected to the lower surface of the mixing tank 11. The outer cylinder 49 is slidably connected to the lower end of the outer surface of the inner cylinder 48. The outer cylinder 49 is also fixedly connected to the inner wall of the support plate 47. The irregular cam 51 is rotatably connected to the inner wall of the support plate 47. The irregular cam 51 is also slidably connected to the outer surface of the second rotating shaft 52.

[0050] like Figure 12 As shown, a rotating shaft is fixedly connected to the center of the handle 43 and the third bevel gear 44. The rotating shaft is rotatably connected to the inner wall of the vertical plate 42. The support plate 47 is slidably connected to the vertical plate 42. Bearing seats are rotatably connected to the upper and lower ends of the outer surface of the threaded rod 46. The bottom ends of the bearing seats are fixedly connected to the upper surface of the vertical plate 42, limiting the threaded rod 46 to rotate only. The outer cylinder 49, inner cylinder 48, and irregular cam 51 are installed and shaped as follows. Figure 12As shown, the mixing tank 11 has a discharge port on the inner wall at the bottom. The inner cylinder 48 is fixed to the discharge port. The irregular cam 51 and the second rotating shaft 52 are splined. The irregular cam 51 can slide up and down on the outer surface of the second rotating shaft 52, and when the second rotating shaft 52 rotates, it can also drive the irregular cam 51 to rotate. The support plate 47 has a self-locking function under the threaded connection of the threaded rod 46. The support plate 47 can provide a certain support for the outer cylinder 49 and the irregular cam 51. When it is necessary to adjust the filling capacity of the loading cylinder 54, that is, to adjust the size of each batch production, the size of the batch production can be adjusted by turning the handle 43. When the handle 43 rotates, it drives the corresponding third bevel gear 44 to rotate. The rotation of the third bevel gear 44, through meshing, drives the fourth bevel gear 45 to rotate. The rotation of the fourth bevel gear 45, in turn, drives the corresponding threaded rod 46 to rotate. When the threaded rod 46 rotates, it causes the support plate 47 to move up or down through the threaded connection with the support plate 47. When the support plate 47 moves up or down, it causes the outer cylinder 49 and the irregular cam 51 to move down or up synchronously. The upward or downward movement of the outer cylinder 49 adjusts the overall length of the loading cylinder 54, thereby adjusting the amount of material in the loading cylinder 54. In batch production, it can also adjust the amount of material produced in each batch.

[0051] A method for using a flexible curtain wall coating material production equipment includes the following steps:

[0052] After S1 pours the material into the mixing tank 11, the first motor 5 is started, which will cause the mixing shaft 14 to rotate, rotate in a circle and move back and forth, so as to mix and stir the material in the mixing tank 11 over a large area.

[0053] After starting the first motor 5, S2 will drive the scraper 22 to work. While rotating in a circle, the scraper 22 can move outward to contact the inner wall of the mixing tank 11 and then move downward to scrape the material adhering to the mixing tank 11 downward.

[0054] After the mixing is completed, S3 starts the second motor 28, which will pour equal amounts of material into the receiving cylinder 41 in sequence and evenly. Turning the handle 43 can adjust the amount of material poured into the receiving cylinder 41.

[0055] In use, after pouring the materials into the mixing tank 11, the first motor 5 is started, which causes the mixing shaft 14 to rotate, rotate in a circle, and move back and forth, thus mixing the materials in the mixing tank 11 over a large area evenly. After starting the first motor 5, the scraper 22 is also driven to work. While rotating in a circle, the scraper 22 can also move outward to contact the inner wall of the mixing tank 11 and then move downward to scrape the materials adhering to the mixing tank 11 downward. After the mixing is completed, the second motor 28 is started, which causes equal amounts of materials to be poured into the receiving cylinder 41 in sequence and evenly. The amount of materials poured into the receiving cylinder 41 can be adjusted by turning the handle 43.

[0056] The specific embodiments described herein are merely illustrative of the spirit of the invention. Those skilled in the art to which this invention pertains may make various modifications or additions to the described specific embodiments or use similar methods to replace them, without departing from the spirit of the invention or exceeding the scope defined by the appended claims.

Claims

1. A flexible curtain wall coating material production equipment, comprising a base plate (1), characterized in that: The bottom plate (1) is provided with a mixing tank (11) at the upper end. The mixing tank (11) is provided with a rotatable first rotating shaft (6) at the upper end. The first rotating shaft (6) is provided with a scraper (22) that cooperates with the inner wall of the mixing tank (11) at the lower end. When the first rotating shaft (6) rotates, the scraper (22) can rotate around the inner wall of the mixing tank (11) and move outward and then downward. The mixing tank (11) is provided with a loading cylinder (54) at the lower end. The loading cylinder (54) is provided with a sealing cover (50) at the lower end. The loading cylinder (54) is provided with a rotatable second rotating shaft (52) at the rear side. The bottom plate (1) is also provided with multiple receiving cylinders (41) at the upper end. When the second rotating shaft (52) rotates, the sealing cover (50) can be flipped downward intermittently and the receiving cylinders (41) can be moved synchronously intermittently. A support arm (3) is fixed to the rear side of the upper surface of the base plate (1). A first motor (5) is fixed to the upper end of the support arm (3). A first rotating shaft (6) is fixed to the lower end of the first motor (5). A spur gear (7) is fixed to the outer surface of the first rotating shaft (6). A planetary spur gear (8) meshes with the outer surface of the spur gear (7). An internal gear ring (9) is fixed to the inner wall of the upper end of the mixing tank (11). The planetary spur gear (8) meshes inside the internal gear ring (9). A first support plate (10) is provided at the lower end of the spur gear (7). The planetary spur gear (8) is rotatably connected to the first support plate (10). The scraper (22) is installed on one side of the lower end of the first support plate (10). The lower end of the planetary spur gear (8) is coaxially fixed with a planar cam (24), and the lower surface of the planar cam (24) is meshed with a second sliding pin (26). The lower surface of the first support plate (10) is fixed with an L-shaped support seat (25), and the second sliding pin (26) is slidably connected inside the L-shaped support seat (25). The lower surface of the first support plate (10) is also slidably connected with a multi-stage telescopic rod (23). The scraper (22) is fixed to the lower surface of the multi-stage telescopic rod (23). The lower end of the outer surface of the second sliding pin (26) is fixed with a push rod (27), and the other end of the push rod (27) is fixed to the multi-stage telescopic rod (23). The upper end of the planetary spur gear (8) is coaxially fixed with a cylindrical cam (17), the outer surface of the cylindrical cam (17) is meshed with a first sliding pin (18), the outer surface of the first sliding pin (18) is fixed with a downwardly extending L-shaped connecting rod (19), the rear end surface of the first support plate (10) is fixed with a limit block (20), the L-shaped connecting rod (19) is slidably connected to the surface of the limit block (20), the front end of the scraper (22) is provided with an extension plate (21), and the L-shaped connecting rod (19) is slidably connected to the extension plate (21); The upper surface of the base plate (1) is fixedly connected to a second motor (28), the front end of the second motor (28) is fixedly connected to a driving bevel gear (29), the front end of the driving bevel gear (29) meshes with a driven bevel gear (30), the second rotating shaft (52) is fixedly connected to the driven bevel gear (30), the upper end of the outer surface of the second rotating shaft (52) is provided with a special-shaped cam (51), the sealing cover (50) is hinged to the lower surface of the loading cylinder (54), and the rear side of the sealing cover (50) is also provided with an extension rod (53) that cooperates with the special-shaped cam (51). The lower end of the outer surface of the second rotating shaft (52) is fixedly connected to an incomplete spur gear (31). The upper surface of the base plate (1) is also rotatably connected to a driven spur gear (32) that cooperates with the incomplete spur gear (31). The lower end of the incomplete spur gear (31) is coaxially fixedly connected to a sector-shaped locking wheel (33). The lower end of the driven spur gear (32) is coaxially fixedly connected to a concave locking wheel (34) that cooperates with the sector-shaped locking wheel (33). The lower end of the concave locking wheel (34) is coaxially fixedly connected to a driving pulley (35). The driving pulley (35) is coaxially fixedly connected to a driving pulley (36). 5) A driven pulley (36) is connected to the left side belt. A first bevel gear (37) is coaxially fixed to the upper end of the driven pulley (36). A second bevel gear (38) meshes with the upper end of the first bevel gear (37). A main friction wheel (39) is coaxially fixed to the front end of the second bevel gear (38). A secondary friction wheel (40) is also rotatably connected to the upper end of the base plate (1). A transmission belt is fitted on the outer surface of the main friction wheel (39) and the secondary friction wheel (40). The receiving cylinder (41) is evenly placed on the conveyor belt.

2. The flexible curtain wall coating material production equipment as described in claim 1, characterized in that: A crank (12) is fixedly connected to the lower end of the outer surface of the first rotating shaft (6), and a rocker arm (13) is hinged to the other end of the crank (12). A stirring shaft (14) is slidably connected inside the first support plate (10). The other end of the rocker arm (13) is rotatably connected to the stirring shaft (14). A small spur gear (15) is fixedly connected to the upper end of the outer surface of the stirring shaft (14). A spur rack (16) that meshes with the small spur gear (15) is fixedly connected to the lower end surface of the first support plate (10). Multiple stirring rods are fixedly connected to the outer surface of the stirring shaft (14).

3. The flexible curtain wall coating material production equipment as described in claim 1, characterized in that: A vertical plate (42) is fixedly connected to the front side of the upper surface of the base plate (1). A support plate (47) is slidably connected to the upper side of the rear surface of the vertical plate (42). A handle (43) is rotatably connected to the lower side of the front surface of the vertical plate (42). A third bevel gear (44) is coaxially fixedly connected to the rear end of the handle (43). A fourth bevel gear (45) meshes with the lower end of the third bevel gear (44). A threaded rod (46) rotatably connected to the vertical plate (42) is fixedly connected at the center of the fourth bevel gear (45). The support plate ( 47) The threaded connection is on the outer surface of the threaded rod (46). The loading cylinder (54) includes an inner cylinder (48) and an outer cylinder (49). The inner cylinder (48) is fixed to the lower end surface of the mixing tank (11). The outer cylinder (49) is slidably connected to the lower end of the outer surface of the inner cylinder (48). The outer cylinder (49) is also fixed inside the support plate (47). The shaped cam (51) is rotatably connected to the lower end surface of the support plate (47). The shaped cam (51) is also slidably connected to the outer surface of the second rotating shaft (52).

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