CN114950216B - Preparation equipment of oxidized nail dispersion liquid applied to ceramic coating - Google Patents

Abstract

The application discloses a preparation device of an oxidation nail dispersion liquid applied to a ceramic coating, which belongs to the technical field of oxidation nail dispersion liquid, wherein different materials with different proportions are filled into a preparation cylinder for mixing treatment, the prepared dispersion liquid is not up to standard due to insufficient mixing, the preparation device comprises a bottom mounting table, an upper mounting table is fixedly arranged on the upper surface of the bottom mounting table, a piston rod slides back and forth along a sliding sleeve and is respectively injected into a water tank and an acid liquid tank through a three-way air pipe, so that water and acid liquid flow into the mixing cylinder through a liquid discharge pipe and a hose, powdery oxidation nails in a storage cylinder enter a rectangular groove of a quantitative cylinder through a feed chute of a spherical block, the quantitative cylinder is driven to rotate in a reciprocating manner through a third gear, the oxidation nails in the rectangular groove enter the mixing cylinder through a conical cylinder and a hose, and a motor drives a first connecting rod and a pull rod to move through a second gear, and the mixing cylinder can continuously shake, so that quantitative feeding and uniform mixing are realized.

Description

Preparation equipment of oxidized nail dispersion liquid applied to ceramic coating

Technical Field

The application relates to the technical field of oxidized nail dispersion liquid, in particular to preparation equipment of oxidized nail dispersion liquid applied to a ceramic coating.

Background

When the common material of the ceramic coating is the oxidized nail dispersion liquid, and the oxidized nail dispersion liquid is usually prepared, the traditional mode is to uniformly fill different materials with a proportioned proportion into a preparation cylinder for mixing treatment, so that the prepared dispersion liquid does not reach the standard due to insufficient mixing, and therefore, the preparation equipment of the oxidized nail dispersion liquid applied to the ceramic coating is provided for solving the problems.

Disclosure of Invention

The application aims to provide a preparation device of an oxidized nail dispersion liquid applied to a ceramic coating, which solves the problems in the prior art.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides a be applied to preparation equipment of oxidation nail dispersion of ceramic coating, includes end mount table, end mount table upper surface fixed is equipped with the mount table, end mount table upper surface slidable mounting shakes even subassembly, end mount table upper surface rotates to articulate there is the mixing drum, mixing drum and last mount table fixed connection, drive arrangement is installed to end mount table bottom, drive arrangement and shake even subassembly fixed connection, drive arrangement fixedly connected with round trip the subassembly, round trip the subassembly and rotate and be connected with the promotion subassembly, round trip the subassembly and the fixed upper surface of mount table that locates of promotion subassembly, the laminating is connected with quantitative subassembly in the promotion subassembly rotation, the fixed connection of promotion subassembly has liquid material conveying mechanism, quantitative subassembly rotates and is connected with the powder material jar, liquid material conveying mechanism and powder material jar are fixed to be located the mount table upper surface.

As a preferable technical scheme of the application, the upper surface of the bottom mounting table is provided with a first convex chute, and the first convex chute is in sliding connection with the shaking-up assembly.

As a preferable technical scheme of the application, a liquid outlet pipe is fixedly arranged on the mixing drum, an upper cover is fixedly arranged at the upper end of the mixing drum, three hoses are fixedly arranged in the upper cover, the upper ends of the hoses are respectively fixedly connected with a liquid material conveying mechanism and a powder material tank, two spring seats are fixedly arranged on the upper surface of the upper cover, connecting rods are fixedly arranged at the upper ends of the spring seats, two ends of each connecting rod are fixedly connected with an upper mounting table, a sliding rod seat is rotatably hinged to the bottom surface of the mixing drum, the bottom end of each sliding rod seat is rotatably hinged to a bottom mounting table, the bottom end of the mixing drum is rotatably hinged to a shaking component, a base is fixedly arranged on the bottom surface of the mixing drum, a hinged seat is rotatably connected to the bottom end of each hinged seat, and the bottom end of each hinged seat is fixedly arranged on the upper surface of the bottom mounting table.

As a preferable technical scheme of the application, the shaking-up assembly comprises a first gear, the bottom surface of the first gear is fixedly connected with a driving device, the first gear is connected with a second gear in a meshed manner, the second gear is rotationally arranged on the upper surface of the bottom mounting table, a first connecting rod is rotationally arranged on the upper surface of the second gear, one end of the first connecting rod is rotationally hinged with a sliding seat, the bottom end of the sliding seat is slidingly arranged in a first convex sliding groove, a pull rod is rotationally hinged with the sliding seat, and the upper end of the pull rod is rotationally hinged with the bottom end of the mixing drum.

As a preferable technical scheme of the application, the driving device comprises a motor, the motor is fixedly connected with a bottom mounting table, a rotary table and an L-shaped deflector rod are fixedly arranged at the output end of the motor, the output end of the motor is fixedly connected with the bottom surface of a first gear, the outer surface of the rotary table is rotationally and fixedly connected with an intermittent plate, a first arc-shaped groove is formed in the rotary table, a plurality of second arc-shaped grooves and rectangular sliding grooves are formed in the intermittent plate, the L-shaped deflector rod is slidably arranged in the rectangular sliding grooves, the outer surface of the rotary table is rotationally and fixedly connected with an inner arc surface of the second arc-shaped groove, a transmission shaft is fixedly arranged on the intermittent plate and is rotationally connected with an upper mounting table, and the upper end of the transmission shaft is fixedly connected with a reciprocating assembly.

As a preferable technical scheme of the application, the reciprocating assembly comprises a half-face gear, the bottom surface of the half-face gear is fixedly connected with a transmission shaft, the half-face gear is in meshed connection with a toothed plate, guide blocks are sleeved outside two ends of the toothed plate in a sliding manner, the bottom surface of each guide block is fixedly connected with a support, the bottom end of each support is fixedly connected with the upper surface of an upper mounting table, the side surface of the toothed plate is rotationally connected with a second connecting rod, and one end of the second connecting rod is rotationally connected with a pushing assembly.

As a preferable technical scheme of the application, the pushing component comprises a disc, the surface of the disc is rotationally connected with a second connecting rod, the disc is rotationally connected with a T-shaped frame, the bottom end of the T-shaped frame is fixedly arranged on the upper surface of the upper mounting table, the disc is fixedly connected with a first cam and a second cam, the outer surface of the first cam is rotationally and closely connected with the quantitative component, the outer surface of the second cam is rotationally and closely connected with a piston rod, the outer side of the piston rod is in sliding sleeve connection with a sliding sleeve, a spring is arranged in the sliding sleeve, an air exchanging pipe is fixedly arranged outside the sliding sleeve, and the bottom end of the sliding sleeve is fixedly connected with a liquid material conveying mechanism.

As a preferable technical scheme of the application, the liquid material conveying mechanism comprises a water tank and an acid liquid tank, wherein the bottoms of the water tank and the acid liquid tank are fixedly arranged on the upper surface of an upper mounting table, filling pipes and liquid discharge pipes are fixedly arranged on the water tank and the acid liquid tank, three-way air pipes are fixedly connected to the water tank and the acid liquid tank, one end of each three-way air pipe is fixedly connected with the bottom end of a sliding sleeve, and the bottoms of the two liquid discharge pipes penetrate through the upper mounting table and are fixedly connected with two hoses.

As a preferable technical scheme of the application, the quantitative assembly comprises an L-shaped pushing shaft, a guide plate is connected to the outer side of the L-shaped pushing shaft in a sliding manner, a fixing strip is fixedly connected to the bottom end of the guide plate, the fixing strip is fixedly connected with a T-shaped frame, a second convex sliding groove is formed in the side face of the fixing strip, a rack is connected to the inner side of the second convex sliding groove in a sliding manner, one end of the L-shaped pushing shaft is attached to the outer surface of a first cam, the other end of the L-shaped pushing shaft is fixedly connected with the rack, a third gear is connected to the rack in a meshed manner, the third gear is connected with a powder tank in a rotating manner, and a first spring is fixedly arranged between the L-shaped pushing shaft and the guide plate.

As a preferable technical scheme of the application, the powder charging bucket comprises a storage cylinder, a feeding pipe is fixedly arranged on the upper surface of the storage cylinder, the storage cylinder is rotationally connected with a third gear, a spherical block is fixedly arranged in the storage cylinder, a feeding groove and a rotary groove are formed in the spherical block, a quantitative cylinder is rotationally and fixedly connected with the inner wall of the rotary groove, a rectangular groove is formed in the quantitative cylinder, a bottom cylinder is fixedly connected with the bottom end of the storage cylinder, a conical cylinder is fixedly arranged on the inner wall of the bottom cylinder, the bottom end of the bottom cylinder is fixedly arranged on the upper surface of an upper mounting table, a feeding pipe is fixedly sleeved at the bottom end of the conical cylinder, and the bottom end of the feeding pipe penetrates through the upper mounting table and is fixedly connected with a hose.

Compared with the prior art, the application has the beneficial effects that:

1. the piston rod slides back and forth in the sliding sleeve, and is respectively injected into the water tank and the acid liquid tank through the three-way air pipe, so that water and acid liquid flow into the mixing drum through the liquid discharge pipe and the hose, and powdery oxidation nails in the storage drum enter the rectangular groove of the quantitative drum through the feeding groove of the spherical block, and drive the quantitative drum to rotate back and forth through the third gear, so that the oxidation nails in the rectangular groove enter the mixing drum through the conical drum and the hose, and meanwhile, the motor drives the first connecting rod and the pull rod to move through the second gear, so that the mixing drum can continuously shake, and quantitative feeding and uniform mixing are realized.

Drawings

Figure 1 is a schematic diagram of the structure of the present application,

figure 2 is a schematic view of the installation of the structural driving device of the present application,

figure 3 is a schematic view of a mixing drum according to the application,

figure 4 is a schematic view of the structural drive device and shaking-up assembly of the present application,

figure 5 is a schematic diagram of a liquid material conveying mechanism with the structure of the application,

figure 6 is a schematic diagram of the round trip assembly of the present application,

figure 7 is a schematic view of the structural pushing assembly of the present application,

FIG. 8 is a schematic view of a powder tank with the structure of the application.

In the figure: 1. a bottom mounting table; 11. a first convex chute; 12. an upper mounting table; 2. a mixing drum; 21. an upper cover; 22. a liquid outlet pipe; 23. a base; 24. a hinged support; 25. a slide bar seat; 26. a spring seat; 27. a connecting rod; 28. a hose; 3. shaking up the assembly; 31. a first gear; 32. a second gear; 33. a first link; 34. a slide; 35. a pull rod; 4. a driving device; 41. a motor; 42. a turntable; 421. a first arc-shaped groove; 43. an intermittent plate; 431. a second arc-shaped groove; 432. rectangular sliding grooves; 44. an L-shaped deflector rod; 45. a transmission shaft; 5. a shuttle assembly; 51. half face gear; 52. a bracket; 53. a toothed plate; 54. a guide block; 55. a second link; 6. a pushing assembly; 61. a disc; 62. a T-shaped frame; 63. a first cam; 64. a second cam; 65. a piston rod; 66. a sliding sleeve; 661. an air exchanging pipe; 7. a liquid material conveying mechanism; 71. a water tank; 72. an acid liquid tank; 73. a filling pipe; 74. a three-way air pipe; 75. a liquid discharge pipe; 8. a powder material tank; 81. a storage cylinder; 811. a feed pipe; 82. a spherical block; 821. a feed chute; 822. a rotary groove; 83. a quantitative cylinder; 831. rectangular grooves; 85. a conical cylinder; 86. a bottom cylinder; 87. a feed pipe; 9. a dosing assembly; 91. an L-shaped pushing shaft; 92. a guide plate; 94. a first spring; 95. a fixing strip; 951. the second convex chute; 96. a rack; 97. and a third gear.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Examples: as shown in fig. 1-8, the application provides a preparation device of an oxidized nail dispersion applied to a ceramic coating, which comprises a bottom mounting table 1, wherein an upper mounting table 12 is fixedly arranged on the upper surface of the bottom mounting table 1, a shaking component 3 is slidably arranged on the upper surface of the bottom mounting table 1, a mixing drum 2 is rotatably hinged to the upper surface of the bottom mounting table 1, the mixing drum 2 is fixedly connected with the upper mounting table 12, a driving device 4 is arranged at the bottom end of the bottom mounting table 1, the driving device 4 is fixedly connected with the shaking component 3, the driving device 4 drives the mixing drum 2 to shake through the shaking component 3, a round trip component 5 is fixedly connected with the round trip component 5, a pushing component 6 is rotatably connected with the driving device 4, the round trip component 5 and the pushing component 6 are fixedly arranged on the upper surface of the upper mounting table 12, a quantitative component 9 is rotatably attached to the pushing component 6, a liquid material conveying mechanism 7 is fixedly connected with the quantitative component 9, a powder material tank 8 is rotatably connected with the quantitative material conveying mechanism 7, the quantitative material conveying mechanism 7 and the powder material tank 8 is fixedly arranged on the surface of the powder material conveying component 8 through the round trip component 5.

Further, a first convex sliding groove 11 is formed in the upper surface of the bottom mounting table 1, and the shaking assembly 3 is slidably connected with the first convex sliding groove 11, so that the shaking assembly 3 can work stably.

Further, the liquid outlet pipe 22 is fixedly arranged on the mixing drum 2, the upper cover 21 is fixedly arranged at the upper end of the mixing drum 2, three hoses 28 are fixedly arranged in the upper cover 21, the upper ends of the hoses 28 are respectively fixedly connected with the liquid material conveying mechanism 7 and the powder material tank 8, so that when the mixing drum 2 shakes, the liquid material conveying mechanism 7 and the powder material tank 8 can be conveyed into the mixing drum 2 through the three hoses 28, two spring seats 26 are fixedly arranged on the upper surface of the upper cover 21, connecting rods 27 are fixedly arranged at the upper ends of the spring seats 26, the two ends of the connecting rods 27 are fixedly connected with the upper mounting table 12, the powder material tank 8 is fixedly connected with the upper mounting table 12 through the two spring seats 26, the mixing drum 2 can keep a vertical and flat state under the self-weight condition, the bottom surface of the mixing drum 2 is rotatably hinged with a slide bar seat 25, the bottom end of the slide bar seat 25 is rotatably hinged with the bottom mounting table 1, when the mixing drum 2 is driven by the shaking component 3, the mixing drum 2 can be smoothly moved through the slide bar seat 25, the bottom surface of the mixing drum 2 can be fixedly arranged on the bottom surface of the mixing drum 2, the bottom seat is fixedly connected with the bottom seat 24, and the bottom seat 24 can be fixedly arranged on the bottom seat 24.

Further, the shaking-up assembly 3 comprises a first gear 31, the bottom surface of the first gear 31 is fixedly connected with the driving device 4, the first gear 31 is connected with a second gear 32 in a meshed manner, the first gear 31 drives the second gear 32 to rotate, the second gear 32 is rotationally arranged on the upper surface of the bottom mounting table 1, a first connecting rod 33 is rotationally arranged on the upper surface of the second gear 32, one end of the first connecting rod 33 is rotationally hinged with a sliding seat 34, the bottom end of the sliding seat 34 is slidingly arranged in the first convex sliding groove 11, a pull rod 35 is rotationally hinged with the sliding seat 34, and the upper end of the pull rod 35 is rotationally hinged with the bottom end of the mixing drum 2, so that the second gear 32 drives the mixing drum 2 to shake by driving the first connecting rod 33 to move, and the pull rod 35 drives the mixing drum 2 to shake.

Further, the driving device 4 includes a motor 41, the bottom mounting table 1 is fixedly connected to the motor 41, a turntable 42 and an L-shaped deflector rod 44 are fixedly provided at the output end of the motor 41, the motor 41 drives the turntable 42 and the L-shaped deflector rod 44 to rotate, the output end of the motor 41 is fixedly connected to the bottom surface of the first gear 31, the outer surface of the turntable 42 is rotationally attached to the second arc-shaped groove 431, a first arc-shaped groove 421 is provided on the turntable 42, a plurality of second arc-shaped grooves 431 and rectangular sliding grooves 432 are provided on the intermittent disk 43, the L-shaped deflector rod 44 is slidably provided in the rectangular sliding grooves 432, the outer surface of the turntable 42 is rotationally attached to the inner arc surface of the second arc-shaped groove 431, a transmission shaft 45 is fixedly provided on the intermittent disk 43, the transmission shaft 45 is rotationally connected with the upper mounting table 12, and the upper end of the transmission shaft 45 is fixedly connected to the reciprocating assembly 5, when the L-shaped deflector rod 44 rotates to be separated from the rectangular sliding grooves 432, the outer surface of the turntable 42 is rotationally attached to the inner arc surface of the second arc-shaped groove 431, so that the intermittent disk 43 does not continuously rotate with inertia, and the transmission shaft 45 can drive the assembly 5 to intermittently work.

Further, the reciprocating assembly 5 comprises a half-face gear 51, the bottom surface of the half-face gear 51 is fixedly connected with a transmission shaft 45, the half-face gear 51 is in meshed connection with a toothed plate 53, guide blocks 54 are sleeved outside two ends of the toothed plate 53 in a sliding manner, the bottom surface of each guide block 54 is fixedly connected with a support 52, the bottom end of each support 52 is fixedly connected with the upper surface of the mounting table 12, the side surface of the toothed plate 53 is rotatably connected with a second connecting rod 55, one end of each second connecting rod 55 is rotatably connected with the pushing assembly 6, and accordingly the half-face gear 51 drives the toothed plate 53 to reciprocate, and the pushing assembly 6 works through the second connecting rod 55.

Further, the pushing component 6 comprises a disc 61, the surface of the disc 61 is rotationally connected with the second connecting rod 55, the second connecting rod 55 drives the disc 61 to reciprocally rotate, the disc 61 is rotationally connected with a T-shaped frame 62, the bottom end of the T-shaped frame 62 is fixedly arranged on the upper surface of the upper mounting table 12, the disc 61 is fixedly connected with a first cam 63 and a second cam 64, the outer surface of the first cam 63 is rotationally and closely connected with the quantifying component 9, the outer surface of the second cam 64 is rotationally and closely connected with a piston rod 65, a sliding sleeve 66 is slidably sleeved outside the piston rod 65, a spring is arranged in the sliding sleeve 66, the second cam 64 pushes the piston rod 65 to slide in the sliding sleeve 66 and extrudes the spring, the piston rod 65 can be reset through the reverse acting force of the spring, a ventilation pipe 661 is fixedly arranged outside the sliding sleeve 66, a one-way valve is arranged in the ventilation pipe 661, and the bottom end of the sliding sleeve 66 is fixedly connected with the liquid material conveying mechanism 7, so that the liquid material conveying mechanism 7 and the quantifying component 9 are reciprocally moved through the first cam 63 and the second cam 64 which reciprocally rotate.

Further, the liquid material conveying mechanism 7 comprises a water tank 71 and an acid liquid tank 72, the bottom ends of the water tank 71 and the acid liquid tank 72 are fixedly arranged on the upper surface of the upper mounting table 12, a filling pipe 73 and a liquid discharge pipe 75 are fixedly arranged on the water tank 71 and the acid liquid tank 72, three-way air pipes 74 are fixedly connected to the water tank 71 and the acid liquid tank 72, one ends of the three-way air pipes 74 are fixedly connected with the bottom ends of the sliding sleeves 66, the two bottom ends of the liquid discharge pipes 75 penetrate through the upper mounting table 12 and are fixedly connected with the two hoses 28, so that the liquid can slide back and forth along the sliding sleeves 66 through the piston rods 65, and can be respectively injected into the water tank 71 and the acid liquid tank 72 through the three-way air pipes 74, so that the liquid in the water tank 71 and the acid liquid tank 72 can flow into the hoses 28 through the liquid discharge pipes 75.

Further, the dosing assembly 9 includes an L-shaped pushing shaft 91, a guide plate 92 is slidably connected to the outside of the L-shaped pushing shaft 91, a fixing strip 95 is fixedly connected to the bottom end of the guide plate 92, the fixing strip 95 is fixedly connected to the T-shaped frame 62, a second convex sliding groove 951 is formed in the side surface of the fixing strip 95, a rack 96 is slidably connected to the second convex sliding groove 951, one end of the L-shaped pushing shaft 91 is attached to the outer surface of the first cam 63, the other end of the L-shaped pushing shaft 91 is fixedly connected to the rack 96, a third gear 97 is engaged and connected to the rack 96, the third gear 97 is rotatably connected to the powder tank 8, and a first spring 94 is fixedly arranged between the L-shaped pushing shaft 91 and the guide plate 92, so that the first cam 63 pushes the L-shaped pushing shaft 91 to move along the guide plate 92, the rack 96 drives the third gear 97 to rotate, and the L-shaped pushing shaft 91 can reset through the reverse acting force of the first spring 94, so that the rack 96 can reciprocate.

Further, the powder charging bucket 8 comprises a storage cylinder 81, a feeding pipe 811 is fixedly arranged on the upper surface of the storage cylinder 81, the storage cylinder 81 is rotationally connected with a third gear 97, a spherical block 82 is fixedly arranged in the storage cylinder 81, a feeding groove 821 and a rotary groove 822 are formed in the spherical block 82, a quantitative cylinder 83 is rotationally attached to the inner wall of the rotary groove 822, the quantitative cylinder 83 is fixedly connected with the third gear 97, a rectangular groove 831 is formed in the quantitative cylinder 83, a bottom cylinder 86 is fixedly connected to the bottom end of the storage cylinder 81, a conical cylinder 85 is fixedly arranged on the inner wall of the bottom cylinder 86, the bottom end of the bottom cylinder 86 is fixedly arranged on the upper surface of the upper mounting table 12, a feeding pipe 87 is fixedly sleeved at the bottom end of the conical cylinder 85, the bottom end of the feeding pipe 87 penetrates through the upper mounting table 12, and a hose 28 is fixedly connected, so that powder oxidized nails in the storage cylinder 81 are driven by the feeding groove 821 of the spherical block 82 to enter the rectangular groove 831 of the quantitative cylinder 83, and the oxidized nails 87 are driven to reciprocate by the third gear 97, and fall into the hose 831 from the conical cylinder 85 to the hose 831.

Working principle: the motor 41 drives the rotary disc 42 and the L-shaped deflector rod 44 to rotate, and rotates the intermittent disc 43 through the rotation of the L-shaped deflector rod 44, the motor 41 drives the second gear 32 to continuously rotate through the first gear 31, so that the second gear 32 drives the first connecting rod 33 to move, the sliding seat 34 slides reciprocally along the first convex sliding groove 11, the pull rod 35 drives the mixing drum 2 to shake along the hinged support 24, the mixing drum 2 can shake smoothly through the two spring seats 26 and the one sliding rod seat 25, when the mixing drum 2 shakes smoothly, raw materials can be conveyed into the mixing drum 2 through the three hoses 28, when the L-shaped deflector rod 44 rotates to be separated from the rectangular sliding groove 432, the outer surface of the rotary disc 42 rotates to be attached to the inner arc surface of the second arc-shaped groove 431, the intermittent disc 43 cannot continuously rotate along with inertia, the transmission shaft 45 can intermittently drive the toothed plate 53 to move reciprocally through intermittent feeding, continuously shaking during feeding so as to uniformly mix, the toothed plate 53 drives the disc 61 to reciprocate through the second connecting rod 55, so that the second cam 64 pushes the piston rod 65 to slide along the sliding sleeve 66 and presses the spring, the piston rod 65 can reset through the reverse acting force of the spring, the piston rod 65 can slide along the sliding sleeve 66 back and forth, the liquid in the water tank 71 and the acid liquid tank 72 can be respectively injected into the water tank 71 and the acid liquid tank 72 through the three-way air pipe 74, the liquid in the water tank 71 and the acid liquid tank 72 flows into the hose 28 and the mixing drum 2 through the liquid discharge pipe 75, the first cam 63 pushes the L-shaped pushing shaft 91 to move along the guide plate 92 and the rack 96 drives the third gear 97 to rotate, the L-shaped pushing shaft 91 can reset through the reverse acting force of the first spring 94, the rack 96 can reciprocate, the powdery oxidized nails in the storage drum 81 enter the rectangular groove 831 of the quantifying drum 83 from the feed groove 821 of the spherical block 82, and drives the quantitative cylinder 83 to reciprocally rotate through the third gear 97, so that the oxidized nails in the rectangular grooves 831 fall into the hose 28 from the conical cylinder 85 and the feeding pipe 87.

Although embodiments of the present application have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the application, the scope of which is defined in the appended claims and their equivalents.

Claims (1)

1. The preparation equipment of oxidation nail dispersion applied to ceramic coating, including bottom mount table (1), its characterized in that: the device comprises a bottom mounting table (1), wherein an upper mounting table (12) is fixedly arranged on the upper surface of the bottom mounting table (1), a shaking component (3) is slidably arranged on the upper surface of the bottom mounting table (1), a mixing drum (2) is rotatably hinged to the upper surface of the bottom mounting table (1), the mixing drum (2) is fixedly connected with the upper mounting table (12), a driving device (4) is arranged at the bottom end of the bottom mounting table (1), the driving device (4) is fixedly connected with the shaking component (3), a reciprocating component (5) is fixedly connected with a pushing component (6), the reciprocating component (5) and the pushing component (6) are fixedly arranged on the upper surface of the upper mounting table (12), a quantifying component (9) is rotatably attached to the pushing component (6), a liquid material conveying mechanism (7) is fixedly connected with the quantifying component (9), the quantifying component (9) is rotatably connected with a powder material tank (8), and the liquid material conveying mechanism (7) and the powder material tank (8) are fixedly arranged on the upper surface of the upper mounting table (12);

the upper surface of the bottom mounting table (1) is provided with a first convex chute (11), and the first convex chute (11) is in sliding connection with the shaking-up assembly (3);

the mixing device is characterized in that a liquid outlet pipe (22) is fixedly arranged on the mixing drum (2), an upper cover (21) is fixedly arranged at the upper end of the mixing drum (2), three hoses (28) are fixedly arranged in the upper cover (21), a liquid conveying mechanism (7) and a powder charging bucket (8) are fixedly connected to the upper ends of the hoses (28), two spring seats (26) are fixedly arranged on the upper surface of the upper cover (21), connecting rods (27) are fixedly arranged at the upper ends of the spring seats (26), two ends of each connecting rod (27) are fixedly connected with an upper mounting table (12), a sliding rod seat (25) is rotatably hinged to the bottom surface of the mixing drum (2), the bottom end of the sliding rod seat (25) is rotatably hinged to a bottom mounting table (1), a base (23) is fixedly arranged on the bottom surface of the mixing drum (2), a base (24) is rotatably connected to the bottom end of the base (23), and the bottom end of the base (24) is fixedly arranged on the upper surface of the bottom mounting table (1);

the shaking-up assembly (3) comprises a first gear (31), the bottom surface of the first gear (31) is fixedly connected with a driving device (4), the first gear (31) is connected with a second gear (32) in a meshed mode, the second gear (32) is rotationally arranged on the upper surface of the bottom mounting table (1), a first connecting rod (33) is rotationally arranged on the upper surface of the second gear (32), one end of the first connecting rod (33) is rotationally hinged with a sliding seat (34), the bottom end of the sliding seat (34) is slidingly arranged in the first convex sliding groove (11), a pull rod (35) is rotationally hinged to the bottom end of the mixing drum (2) in a hinged mode, and the upper end of the pull rod (35) is rotationally connected with the bottom end of the mixing drum (2);

the driving device (4) comprises a motor (41), the motor (41) is fixedly connected with a bottom mounting table (1), a rotary table (42) and an L-shaped deflector rod (44) are fixedly arranged at the output end of the motor (41), the output end of the motor (41) is fixedly connected with the bottom surface of a first gear (31), an intermittent disc (43) is rotationally and fixedly connected with the outer surface of the rotary table (42), a first arc-shaped groove (421) is formed in the rotary table (42), a plurality of second arc-shaped grooves (431) and rectangular sliding grooves (432) are formed in the intermittent disc (43), the L-shaped deflector rod (44) is slidingly arranged in the rectangular sliding grooves (432), a transmission shaft (45) is fixedly arranged on the outer surface of the rotary table (42), the transmission shaft (45) is rotationally connected with an upper mounting table (12), and the upper end of the transmission shaft (45) is fixedly connected with a reciprocating assembly (5); the reciprocating assembly (5) comprises a half-face gear (51), the bottom surface of the half-face gear (51) is fixedly connected with a transmission shaft (45), the half-face gear (51) is connected with a toothed plate (53) in a meshed mode, guide blocks (54) are sleeved outside two ends of the toothed plate (53) in a sliding mode, a support (52) is fixedly connected to the bottom surface of the guide blocks (54), the bottom end of the support (52) is fixedly connected with the upper surface of an upper mounting table (12), a second connecting rod (55) is rotatably connected to the side surface of the toothed plate (53), and one end of the second connecting rod (55) is rotatably connected with a pushing assembly (6); the pushing assembly (6) comprises a disc (61), the surface of the disc (61) is rotationally connected with a second connecting rod (55), the disc (61) is rotationally connected with a T-shaped frame (62), the bottom end of the T-shaped frame (62) is fixedly arranged on the upper surface of the upper mounting table (12), the disc (61) is fixedly connected with a first cam (63) and a second cam (64), the outer surface of the first cam (63) is rotationally and fixedly connected with a quantitative assembly (9), the outer surface of the second cam (64) is rotationally and fixedly connected with a piston rod (65), a sliding sleeve (66) is sleeved outside the piston rod (65), a spring is arranged in the sliding sleeve (66), an air exchanging tube (661) is fixedly arranged outside the sliding sleeve (66), and the bottom end of the sliding sleeve (66) is fixedly connected with a liquid material conveying mechanism (7); the automatic feeding device is characterized in that the liquid conveying mechanism (7) comprises a water tank (71) and an acid liquid tank (72), the bottom ends of the water tank (71) and the acid liquid tank (72) are fixedly arranged on the upper surface of the upper mounting table (12), a filling pipe (73) and a liquid discharge pipe (75) are fixedly arranged on the water tank (71) and the acid liquid tank (72), a three-way air pipe (74) is fixedly connected to the water tank (71) and the acid liquid tank (72), one end of the three-way air pipe (74) is fixedly connected with the bottom ends of a sliding sleeve (66), and the bottom ends of the two liquid discharge pipes (75) penetrate through the upper mounting table (12) and are fixedly connected with two hoses (28); the quantitative assembly (9) comprises an L-shaped pushing shaft (91), a guide plate (92) is connected to the outside of the L-shaped pushing shaft (91) in a sliding manner, a fixing strip (95) is fixedly connected to the bottom end of the guide plate (92), a T-shaped frame (62) is fixedly connected to the fixing strip (95), a second convex sliding groove (951) is formed in the side face of the fixing strip (95), a rack (96) is connected to the second convex sliding groove (951) in a sliding manner, one end of the L-shaped pushing shaft (91) is connected to the outer surface of the first cam (63) in a fitting manner, the other end of the L-shaped pushing shaft (91) is fixedly connected with the rack (96), a third gear (97) is connected to the rack (96) in a meshed manner, and a first spring (94) is fixedly arranged between the L-shaped pushing shaft (91) and the guide plate (92); powder material jar (8) is including storage cylinder (81), fixed surface is equipped with inlet pipe (811) on storage cylinder (81), storage cylinder (81) rotate with third gear (97) and are connected, storage cylinder (81) internal fixation is equipped with sphere piece (82), feed chute (821), change groove (822) have been seted up in sphere piece (82), change groove (822) inner wall rotation laminating and be connected with ration section of thick bamboo (83), ration section of thick bamboo (83) and third gear (97) fixed connection, rectangular channel (831) have been seted up on ration section of thick bamboo (83), storage cylinder (81) bottom fixedly connected with end section of thick bamboo (86), end section of thick bamboo (86) inner wall is fixed to be equipped with cone (85), end section of thick bamboo (86) bottom fixed are located on mount table (12) upper surface, cone (85) bottom fixed cup joint feed pipe (87), the feed pipe (87) bottom runs through mount table (12) to a hose (28) of fixed connection.