CN219377636U - Rotatable shower nozzle of pottery 3D nanometer inkjet - Google Patents

Abstract

The utility model discloses a ceramic 3D nanometer ink-jet rotatable spray head, which comprises a mounting plate, a rotating rod, a fixed ring and a spray head main body, wherein the rotating rod is arranged in the mounting plate in a penetrating manner, the fixed ring is fixedly arranged at the front end of the rotating rod, a butt joint hose is fixedly arranged at the left side of the spray head main body, a discharge hole is formed in the lower end of the spray head main body, the fixed rod is fixedly arranged at the outer side of the front end of the rotating rod, and a supporting spring and a moving cylinder are sleeved at the outer side of the fixed rod. This rotatable shower nozzle of pottery 3D nanometer inkjet, the user makes the motion section of thick bamboo keep away from the draw-in groove and slide in the outside of dead lever, and can make the dwang rotate through fixed ring area dynamic shower nozzle main part after the separation of motion section of thick bamboo and draw-in groove, and supporting spring can expand and promote the inside that the motion section of thick bamboo got into another group draw-in groove, through rotating the shower nozzle main part, can effectually change the spraying position of this shower nozzle main part to the suitability of this shower nozzle of effectual improvement.

Description

Rotatable shower nozzle of pottery 3D nanometer inkjet

Technical Field

The utility model relates to the technical field of spray heads, in particular to a ceramic 3D nano ink-jet rotatable spray head.

Background

In the production process of glazed ceramic products, in order to rapidly produce qualified ceramic products, spray ink treatment is generally carried out on ceramic finished products which are not fired by using a spray head, the spray head is generally installed on the outer side of a supporting frame for use, the spray head is controlled to accurately spray ink on the ceramic surface, so that the ceramic surface can look more 3D, the production speed of the glazed ceramic products can be effectively improved by a user through the nano spray head, but certain using defects exist in the using process of part of spray heads, such as:

the utility model discloses a 3D nano-ink-jet printing spray head for glazed ceramics, which has the advantages that the spray head can automatically dredge a spray nozzle through an anti-blocking dredging structure of the spray nozzle when the spray nozzle is blocked, so that the working efficiency is improved, and the labor intensity is reduced;

in the above-mentioned document, shower nozzle shell fixed mounting is in the outside of mounting panel to the mounting panel passes through bolt fixed mounting in the outside of support frame, makes this shower nozzle can only carry out the unidirectional spraying ink at the in-process that this shower nozzle carried out the inkjet, need use other shower nozzles to produce outside different positions to spray ink to ceramic when spraying ink to ceramic finished product outside different positions, leads to this shower nozzle limited application scope in the in-process that uses.

Aiming at the problems, innovative design is urgently needed on the basis of the original spray head structure.

Disclosure of Invention

The utility model aims to provide a ceramic 3D nano ink-jet rotatable spray head, which aims to solve the problem that when the spray head is used for spraying ink on different positions on the outer side of a ceramic finished product, other spray heads are required to be used for spraying ink on different positions on the outer side of the ceramic, so that the spray head has a limited application range in the use process.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a rotatable shower nozzle of pottery 3D nanometer inkjet, includes mounting panel, dwang, solid fixed ring and shower nozzle main part, the inside of mounting panel runs through and installs the dwang, and the front end fixed mounting of dwang has solid fixed ring to gu fixed ring's inside fixed mounting has the shower nozzle main part, the left side fixed mounting of shower nozzle main part has the butt joint hose, and the lower extreme of shower nozzle main part has seted up the discharge gate, the front end outside fixed mounting of dwang has the dead lever, and the outside cover of dead lever is equipped with supporting spring and a motion section of thick bamboo to supporting spring is located the rear end of a motion section of thick bamboo, the one end that the dead lever was kept away from to the motion section of thick bamboo is located the inside of draw-in groove, and the draw-in groove is seted up in the inside of mounting panel.

Preferably, the upper end internal surface fixed mounting of shower nozzle main part has the fixed column, and the lower extreme outer side sliding mounting of fixed column has the sleeve, telescopic lower extreme fixed mounting has first closing plate, and the lower extreme fixed mounting of first closing plate has the second closing plate to the lower extreme fixed mounting of second closing plate has the dredging needle, the movement groove has been seted up on telescopic right side, and the inside slidable mounting of movement groove has first rack, the right side internal surface fixed mounting of shower nozzle main part has the mounting, and the inside slidable mounting of mounting has the motion pole, and the lower extreme fixed mounting of motion pole has the sealing member, and the sealing member runs through the second closing plate simultaneously, the upper end left side fixed mounting of motion pole has the second rack, the inside fixed mounting of shower nozzle main part has electric motor, and the outside fixed mounting of output shaft of electric motor has the gear, can make the dredging needle move in the inside of bin outlet through controlling the motion of dredging needle to avoid this shower nozzle main part to take place to block up.

Preferably, the rotating rod is rotationally connected with the mounting plate, and the rotating rod is fixedly connected with the supporting spring, and the rotating rod is rotationally connected with the mounting plate, so that the rotating rod can drive the spray head main body to rotate in the process of rotating in the mounting plate.

Preferably, the moving cylinder and the mounting plate form a clamping structure through the clamping groove, the moving cylinder and the rotating rod form an elastic structure through the supporting spring, three groups of clamping grooves are formed in the mounting plate, and the moving cylinder and the rotating rod form an elastic structure through the supporting spring so that the moving cylinder can be pushed to move on the outer side of the rotating rod through the supporting spring.

Preferably, the first sealing plate and the second sealing plate are in sliding connection with the inner surface of the nozzle body, the inner surface of the second sealing plate is tightly attached to the outer surface of the sealing piece, and the first sealing plate and the second sealing plate are in sliding connection with the inner surface of the nozzle body, so that ink can be prevented from moving upwards through a gap between the first sealing plate and the nozzle body and between the second sealing plate and the nozzle body.

Preferably, the first rack and the sleeve form a sliding structure through the movement groove, the first rack is connected with the gear in a meshed mode, and the first rack and the sleeve form the sliding structure through the movement groove so that the first rack can slide in the sleeve through the movement groove.

Preferably, the gear is meshed with the second rack, the second rack is fixedly connected with the moving rod, the moving rod is in sliding connection with the first sealing plate and the fixing piece, and the gear can drive the second rack to move in the process of rotating the gear through meshed connection of the gear and the second rack.

Compared with the prior art, the utility model has the beneficial effects that:

1. the ceramic 3D nanometer ink-jet rotatable spray head is characterized in that in the process of rotating the spray head, a user enables a moving cylinder to be far away from a clamping groove and slide on the outer side of a fixed rod, the moving cylinder can squeeze a supporting spring and enable the supporting spring to shrink in the process, the moving cylinder can rotate a spray head main body through a fixed ring after being separated from the clamping groove, the moving cylinder is released after the spray head main body rotates to a required angle, the supporting spring can expand and push the moving cylinder to enter the inner part of another group of clamping groove, so that the rotating cylinder and the spray head main body are fixed at the required angle, and the spraying position of the spray head main body can be effectively changed by rotating the spray head main body, so that the applicability of the spray head is effectively improved;

2. this rotatable shower nozzle of pottery 3D nanometer inkjet, at the in-process that this shower nozzle dredged, the gear can drive first rack and slide downwards, and the second rack then can be under the effect of gear upward movement, the in-process of second rack upward movement then can make sealing member and second closing plate separate, printing ink then can pass the upper end that the second closing plate got into the second closing plate, first rack then can make the mediation needle down move and run through the discharge gate this moment, afterwards electric motor carries out reverse rotation, make the mediation needle keep away from the discharge gate, so reciprocally, alright make the discharge gate dredge and continue to spout ink, so far, the jam mediation process of this shower nozzle has just been accomplished, thereby the effectual anti-blocking effect that has improved this shower nozzle.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model in a front cross-section;

FIG. 2 is a schematic top view of a gear according to the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 4 is a schematic top view of the present utility model;

FIG. 5 is a schematic view of a cross-sectional view of a motion barrel of the present utility model;

fig. 6 is a schematic diagram of a rear view structure of a card slot according to the present utility model.

In the figure: 1. a mounting plate; 2. a rotating lever; 3. a fixing ring; 4. a head main body; 5. docking the hose; 6. a fixed rod; 7. a support spring; 8. a moving cylinder; 9. a clamping groove; 10. fixing the column; 11. a sleeve; 12. a first sealing plate; 13. a second sealing plate; 14. a dredging needle; 15. a discharge port; 16. a movement groove; 17. a first rack; 18. a fixing member; 19. a motion bar; 20. a second rack; 21. a seal; 22. a gear; 23. an electric motor.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present utility model provides a technical solution: the utility model provides a rotatable shower nozzle of pottery 3D nanometer inkjet, includes mounting panel 1, dwang 2, solid fixed ring 3, shower nozzle main part 4, butt joint hose 5, dead lever 6, supporting spring 7, motion section of thick bamboo 8, draw-in groove 9, fixed column 10, sleeve 11, first closing plate 12, second closing plate 13, dredge needle 14, discharge gate 15, motion groove 16, first rack 17, mounting 18, motion pole 19, second rack 20, sealing member 21, gear 22 and electric motor 23.

The inside of mounting panel 1 runs through and installs dwang 2, and the front end fixed mounting of dwang 2 has solid fixed ring 3, and gu fixed ring 3's inside fixed mounting has shower nozzle main part 4, shower nozzle main part 4's left side fixed mounting has butt joint hose 5, and discharge gate 15 has been seted up to shower nozzle main part 4's lower extreme, the front end outside fixed mounting of dwang 2 has dead lever 6, and the outside cover of dead lever 6 is equipped with supporting spring 7 and a movement section of thick bamboo 8, and supporting spring 7 is located the rear end of a movement section of thick bamboo 8, the one end that dead lever 6 was kept away from to movement section of thick bamboo 8 is located the inside of draw-in groove 9, and draw-in groove 9 is seted up in the inside of mounting panel 1, dwang 2 and mounting panel 1 rotate and be connected, and dwang 2 and supporting spring 7 fixed connection, movement section of thick bamboo 8 constitutes the block structure through draw-in groove 9 and mounting panel 1, and movement section of thick bamboo 8 constitutes elastic structure through supporting spring 7 and dwang 2, and draw-in groove 9 is provided with three in the inside of mounting panel 1.

According to fig. 4-6, when the ceramic 3D nano-inkjet rotatable nozzle is used, the nozzle is firstly placed at a position where the nozzle needs to work, the nozzle needs to be adjusted to a required angle before the nozzle is used for performing inkjet, and in the process that the nozzle rotates by a user, the user firstly slides the moving cylinder 8 outside the fixed rod 6 and enables the moving cylinder 8 to be far away from the clamping groove 9, the moving cylinder 8 extrudes the supporting spring 7 and enables the supporting spring 7 to shrink in the process that the moving cylinder 8 moves, the user can rotate the rotating rod 2 after the moving cylinder 8 is separated from the clamping groove 9, the rotating rod 2 can drive the nozzle main body 4 to rotate through the fixed ring 3 in the process that the rotating rod 2 rotates, and the user releases the moving cylinder 8 after the nozzle main body 4 rotates to the required angle, at this time, the compressed supporting spring 7 expands and pushes the moving cylinder 8 to enter the inside the other group of clamping groove 9, so that the nozzle main body 4 is fixed at the required angle, and then the docking hose 5 and the ink supply hose 4 can be docked with the docking device, so that the nozzle main body 4 can be effectively rotated, and the position of the nozzle 4 can be effectively changed.

The inner surface of the upper end of the spray head main body 4 is fixedly provided with a fixed column 10, the outer side of the lower end of the fixed column 10 is slidably provided with a sleeve 11, the lower end of the sleeve 11 is fixedly provided with a first sealing plate 12, the lower end of the first sealing plate 12 is fixedly provided with a second sealing plate 13, the lower end of the second sealing plate 13 is fixedly provided with a dredging needle 14, the right side of the sleeve 11 is provided with a moving groove 16, the inner surface of the moving groove 16 is slidably provided with a first rack 17, the right inner surface of the spray head main body 4 is fixedly provided with a fixing piece 18, the inner side of the fixing piece 18 is slidably provided with a moving rod 19, the lower end of the moving rod 19 is fixedly provided with a sealing piece 21, the sealing piece 21 penetrates through the second sealing plate 13, the left side of the upper end of the moving rod 19 is fixedly provided with a second rack 20, the inner side of the spray head main body 4 is fixedly provided with an electric motor 23, the outer side of an output shaft of the electric motor 23 is fixedly provided with a gear 22, the first sealing plate 12 and the second sealing plate 13 are slidably connected with the inner surface of the spray head main body 4, the inner surface of the second sealing plate 13 is closely attached to the outer surface of the sealing piece 21, the first rack 17 is slidably connected with the first rack 17 and the second rack 20 through the moving groove 16 and the sleeve 11, the first rack 17 is slidably connected with the first rack 20 and the second rack 20, and the second rack 20 is fixedly meshed with the second rack 20.

According to fig. 1-3, in the process of jetting ink from the nozzle, the ink in the ink supply device enters the lower end of the nozzle body 4 through the abutting hose 5 and is ejected through the discharge port 15 at the lower end of the nozzle body 4, and when the lower end of the nozzle body 4 is blocked, the electric motor 23 drives the gear 22 to rotate, the first rack 17 slides downwards in the moving groove 16 in the process of rotating the gear 22, the second rack 20 moves upwards, the sealing member 21 is driven to move by the moving rod 19 in the process of moving the second rack 20 upwards, the sealing member 21 is separated from the second sealing plate 13 in the process of moving upwards, after the sealing member 21 is separated from the second sealing plate 13, the ink at the lower end of the nozzle body 4 passes through the second sealing plate 13 and enters the gap between the second sealing plate 13 and the first sealing plate 12, in the process, the first rack 17 moves to the lower end of the movement groove 16 and moves downwards continuously, the sleeve 11 slides downwards at the outer side of the fixed column 10 in the process of moving downwards, the sleeve 11 pushes the second sealing plate 13 to slide downwards through the first sealing plate 12 in the process of moving downwards, (friction force between the first sealing plate 12 and the second sealing plate 13 and the inner surface of the nozzle body 4 can keep the first sealing plate 12 and the second sealing plate 13 stationary in the inner part of the nozzle body 4), the second sealing plate 13 moves downwards and penetrates the discharge hole 15 through the dredging needle 14 in the process of moving downwards, then the electric motor 23 drives the gear 22 to move reversely, so that the dredging needle 14 moves out of the discharge hole 15, and the inside of the discharge hole 15 is dredged and can continue ink jetting, the blockage dredging process of the spray head is completed, so that the blockage preventing effect of the spray head is effectively improved, and the overall practicability is improved.

What is not described in detail in this specification is prior art known to those skilled in the art.

Although embodiments of the present utility model 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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a rotatable shower nozzle of pottery 3D nanometer inkjet, includes mounting panel (1), dwang (2), solid fixed ring (3) and shower nozzle main part (4), its characterized in that: the inside of mounting panel (1) runs through and installs dwang (2), and the front end fixed mounting of dwang (2) has solid fixed ring (3) to gu fixed mounting in fixed ring (3) has shower nozzle main part (4), the left side fixed mounting of shower nozzle main part (4) has butt joint hose (5), and discharge gate (15) have been seted up to the lower extreme of shower nozzle main part (4), the front end outside fixed mounting of dwang (2) has dead lever (6), and the outside cover of dead lever (6) is equipped with supporting spring (7) and a motion section of thick bamboo (8) to supporting spring (7) are located the rear end of a motion section of thick bamboo (8), the one end that dead lever (6) was kept away from to motion section of thick bamboo (8) is located the inside of draw-in groove (9), and the inside at mounting panel (1) is seted up to draw-in groove (9).

2. The ceramic 3D nano-inkjet rotatable nozzle according to claim 1, wherein: the utility model discloses a shower nozzle, including shower nozzle main part (4), upper end internal surface fixed mounting has fixed column (10), and the lower extreme outside sliding mounting of fixed column (10) has sleeve (11), the lower extreme fixed mounting of sleeve (11) has first closing plate (12), and the lower extreme fixed mounting of first closing plate (12) has second closing plate (13), and the lower extreme fixed mounting of second closing plate (13) has dredging needle (14), movement groove (16) have been seted up on the right side of sleeve (11), and the inside slidable mounting of movement groove (16) has first rack (17), the right side internal surface fixed mounting of shower nozzle main part (4) has mounting (18), and the inside slidable mounting of mounting (18) has moving rod (19), and the lower extreme fixed mounting of moving rod (19) has sealing member (21), and sealing member (21) run through second closing plate (13) simultaneously, the inside fixed mounting of shower nozzle main part (4) has electric motor (23) and electric motor (23) output shaft's the outside of gear (22).

3. The ceramic 3D nano-inkjet rotatable nozzle according to claim 1, wherein: the rotating rod (2) is rotationally connected with the mounting plate (1), and the rotating rod (2) is fixedly connected with the supporting spring (7).

4. The ceramic 3D nano-inkjet rotatable nozzle according to claim 1, wherein: the moving cylinder (8) and the mounting plate (1) form a clamping structure through the clamping groove (9), the moving cylinder (8) and the rotating rod (2) form an elastic structure through the supporting spring (7), and three groups of clamping grooves (9) are formed in the mounting plate (1).

5. The ceramic 3D nano-inkjet rotatable nozzle according to claim 2, wherein: the first sealing plate (12) and the second sealing plate (13) are in sliding connection with the inner surface of the nozzle body (4), and the inner surface of the second sealing plate (13) is tightly attached to the outer surface of the sealing piece (21).

6. The ceramic 3D nano-inkjet rotatable nozzle according to claim 2, wherein: the first rack (17) and the sleeve (11) form a sliding structure through the movement groove (16), and the first rack (17) is connected with the gear (22) in a meshed mode.

7. The ceramic 3D nano-inkjet rotatable nozzle according to claim 2, wherein: the gear (22) is meshed with the second rack (20), the second rack (20) is fixedly connected with the moving rod (19), and the moving rod (19) is in sliding connection with the first sealing plate (12) and the fixing piece (18).