CN217257107U - Glaze ceramic 3D nanometer inkjet printing shower nozzle - Google Patents

Abstract

The utility model discloses a ceramic 3D nanometer inkjet printing nozzle of glaze, include: the air pump is fixedly connected to the mounting plate, one end of the air pipe penetrates through the center of the top of the shell, the other end of the air pipe is fixedly communicated with the air pump, and the air pump is fixedly connected to the mounting plate; further comprising: the plug body is attached to and coaxially arranged on the inner wall of the shell, a first spring is fixedly connected between the upper surface of the plug body and the top of the inner wall of the shell, a partition plate is arranged below the plug body, and the partition plate is coaxially connected to the inner wall of the shell and used for separating a space; and the upper end of the ejector pin is vertically connected to the center of the bottom surface of the plug body. This ceramic 3D nanometer inkjet of glaze prints shower nozzle, it possesses the stifled structure of dredging that prevents of nozzle, when the spout takes place to block up, can dredge the spout automatically to improve work efficiency, reduced intensity of labour.

Description

Glaze ceramic 3D nanometer inkjet printing shower nozzle

Technical Field

The utility model relates to a ceramic ink-jet printing technical field specifically is a ceramic 3D nanometer ink-jet printing nozzle of glaze.

Background

During the production process of glazed ceramic products, users can spray ink on ceramics through an ink-jet printing device so as to form a specific pattern, however, the existing ink-jet printing nozzles still have some problems.

For example, an inkjet printing nozzle with publication number CN110481158B solves the technical problem that when an inkjet printing technology is adopted to print a display film layer in the prior art, the uniformity of the film layer is low, and the display effect is reduced. According to the ink-jet printing nozzle provided by the embodiment of the invention, the spiral blade is arranged in the nozzle, so that … … is formed when the ink-jet printing device sprays ink. It does not possess the stifled structure of dredging that prevents of nozzle, when the spout takes place to block up, needs the manual clearance spout of user to work efficiency has been reduced, intensity of labour has been improved.

In order to solve the problems, innovative design is urgently needed on the basis of the original ink-jet printing nozzle.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a ceramic 3D nanometer inkjet printing shower nozzle of glaze to solve above-mentioned background art and propose current inkjet printing shower nozzle, it does not possess the nozzle prevent stifled mediation structure, when the spout takes place to block up, needs the manual clearance spout of user, thereby has reduced work efficiency, has improved intensity of labour's problem.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a ceramic 3D nanometer inkjet of glaze prints shower nozzle, includes:

the air pump is fixedly connected to the mounting plate, one end of the air pipe penetrates through the center of the top of the shell, the other end of the air pipe is fixedly communicated with the air pump, and the air pump is fixedly connected to the mounting plate;

further comprising:

the plug body is attached to and coaxially arranged on the inner wall of the shell, a first spring is fixedly connected between the upper surface of the plug body and the top of the inner wall of the shell, a partition plate is arranged below the plug body, and the partition plate is coaxially connected to the inner wall of the shell and used for separating a space;

the ejector pin, its upper end is connected perpendicularly in the bottom surface center department of cock body, the ejector pin slide run through in the baffle setting, and the lower extreme coaxial setting of ejector pin is in the top of shell bottom spout to the baffle below is provided with the horizontally transfer line, and the port of transfer line is fixed to run through and is installed on the lateral wall of shell moreover.

Preferably, the baffle is discoid structure, and the laminating is provided with the ejector pad on the bottom surface of baffle to the lateral wall laminating setting of ejector pad is in on the inner wall of shell, fixed through mounting has the thimble of coaxial setting on the ejector pad, makes the thimble drive the ejector pad removal.

Preferably, the bottom surface of the partition plate is vertically connected with guide pillars, the two guide pillars are symmetrically distributed on two sides of the ejector pin, the push block is of a conical structure, the top of the push block is provided with a guide hole, and the guide pillars are slidably embedded in the guide hole to form a guide limiting structure, so that a guide structure of the push block is formed.

Preferably, the shell is kept away from and is link up the one end of installing the connecting pipe on the lateral wall of transfer line, and the other end of connecting pipe is fixed to be run through in the pressure cylinder setting to connecting pipe, transfer line and the coaxial setting of pressure cylinder three make printing ink can get into in the pressure cylinder.

Preferably, the inner wall of the pressure cylinder is provided with a stress disc in a fitting manner, the end face of the stress disc, far away from the connecting pipe, of the stress disc is fixedly connected with a second spring between the inner wall of the pressure cylinder, and the stress disc can move in the pressure cylinder.

Preferably, the second spring housing is established on the lateral wall of interior post, and the one end coaxial coupling of interior post is in on the inner wall of pressure section of thick bamboo to fixed mounting has the switch on the terminal surface of the other end of interior post, and the switch is located moreover the avris of atress dish makes the atress dish can contact with the switch.

Compared with the prior art, the beneficial effects of the utility model are that: this ceramic 3D nanometer inkjet of glaze prints shower nozzle, it possesses the stifled structure of dredging that prevents of nozzle, when the spout takes place to block up, can dredge the spout automatically to improve work efficiency, reduced intensity of labour, its concrete content is as follows:

1. the center of the top of the shell is fixedly provided with one end through which a gas pipe penetrates, the other end of the gas pipe is fixedly communicated with the gas pump, the upper end of the ejector pin is vertically connected to the center of the bottom surface of the plug body, the ejector pin penetrates through the partition plate in a sliding manner, and the lower end of the ejector pin is coaxially arranged above the bottom nozzle of the shell, so that the gas pump can send gas into the shell through the gas pipe, the plug body and the ejector pin are pushed to move downwards by high-pressure gas, and the nozzle is dredged by the ejector pin;

2. fixed mounting's connecting pipe has realized the intercommunication of both inner spaces between pressure tube and the shell, the laminating is provided with the atress dish on the inner wall of pressure tube, fixedly connected with second spring between the terminal surface that the connecting pipe was kept away from to the atress dish and the inner wall of pressure tube, the one end coaxial coupling of inner prop is on the inner wall of pressure tube, the switch of installation is located the avris of atress dish on the other end terminal surface of inner prop, when the printing ink pressure in the shell risees, utilize the oil pressure to promote the movement of atress dish, make atress dish trigger switch.

Drawings

FIG. 1 is a schematic view of the overall external structure of the present invention;

FIG. 2 is a schematic view of the installation structure of the plug body of the present invention;

FIG. 3 is a schematic view of the mounting structure of the push block of the present invention;

FIG. 4 is a schematic view of the installation structure of the force-bearing plate of the present invention;

fig. 5 is a schematic view of the thimble mounting structure of the present invention.

In the figure: 1. a housing; 2. mounting a plate; 3. an air pump; 4. a gas delivery pipe; 5. a plug body; 6. a first spring; 7. a thimble; 8. a partition plate; 9. a guide post; 10. a push block; 11. a transfusion tube; 12. a connecting pipe; 13. a pressure cylinder; 14. a force-bearing disc; 15. a second spring; 16. an inner column; 17. and (4) switching.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: the utility model provides a glaze pottery 3D nanometer inkjet printing shower nozzle, includes:

the air pump comprises a shell 1, an air pump 3 and an air pump, wherein the shell 1 is fixedly connected to the side wall of a mounting plate 2, one end of an air pipe 4 is fixedly penetrated through the center of the top of the shell 1, the other end of the air pipe 4 is fixedly communicated with the air pump 3, and the air pump 3 is fixedly connected to the mounting plate 2;

further comprising:

the plug body 5 is attached to the inner wall of the shell 1 and coaxially arranged with the inner wall of the shell 1, a first spring 6 is fixedly connected between the upper surface of the plug body 5 and the top of the inner wall of the shell 1, a partition plate 8 is arranged below the plug body 5, and the partition plate 8 is coaxially connected to the inner wall of the shell 1 for separating space;

the upper end of the thimble 7 is vertically connected to the center of the bottom surface of the plug body 5, the thimble 7 is arranged to slide through the partition plate 8, the lower end of the thimble 7 is coaxially arranged above the bottom nozzle of the shell 1, a horizontal infusion tube 11 is arranged below the partition plate 8, and the port of the infusion tube 11 is fixedly arranged on the side wall of the shell 1 in a penetrating manner.

The clapboard 8 is in a disc-shaped structure, a push block 10 is attached to the bottom surface of the clapboard 8, the side wall of the push block 10 is attached to the inner wall of the shell 1, a thimble 7 which is coaxially arranged is fixedly arranged on the push block 10 in a penetrating way, a guide post 9 is vertically connected to the bottom surface of the clapboard 8, two guide posts 9 are symmetrically distributed on two sides of the thimble 7, the push block 10 is in a conical structure, the top of the push block 10 is provided with a guide hole, and a guide post 9 is embedded in the guide hole in a sliding way to form a guide limit structure, the plug body 5 is pushed to move downwards by utilizing the pressure difference, the plug body 5 drives the thimble 7 to move synchronously, so that the bottom end of the thimble 7 is dredged through the nozzle at the bottom of the shell 1, the push block 10 moves along the thimble 7, the tapered push block 10 slides downwards along the inner wall of the shell 1, and the push block 10 further extrudes the ink at the bottom of the shell 1, so that the ink can be ejected from the dredged nozzle.

The side wall of the shell 1 far away from the infusion tube 11 is provided with one end of a connecting tube 12 in a through mode, the other end of the connecting tube 12 is fixedly arranged to penetrate through a pressure cylinder 13, the connecting tube 12, the infusion tube 11 and the pressure cylinder 13 are coaxially arranged, the inner wall of the pressure cylinder 13 is provided with a stress disc 14 in a fit mode, a second spring 15 is fixedly connected between the end face of the stress disc 14 far away from the connecting tube 12 and the inner wall of the pressure cylinder 13, the second spring 15 is sleeved on the side wall of an inner column 16, one end of the inner column 16 is coaxially connected to the inner wall of the pressure cylinder 13, a switch 17 is fixedly arranged on the end face of the other end of the inner column 16, the switch 17 is located on the side of the stress disc 14, if a nozzle at the bottom end of the shell 1 is blocked, the ink pressure in the shell 1 rises, at the moment, the ink pressure in the connecting tube 12 and the pressure cylinder 13 rises synchronously, and the stress disc 14 is pushed to move in the pressure cylinder 13 by the change of the pressure difference, so that the force-receiving disc 14 compresses the second spring 15 and the force-receiving disc 14 will come into contact with the switch 17 on the inner post 16.

The working principle is as follows: when the glazed ceramic 3D nano ink-jet printing nozzle is used, firstly, referring to fig. 1-5, a user fixedly connects an external ink supply device with a liquid conveying pipe 11, so that the ink supply device can continuously convey ink into the bottom of a shell 1 through the liquid conveying pipe 11, the ink in the shell 1 enters one side of a pressure cylinder 13 through a connecting pipe 12, the ink is ejected out through a nozzle at the bottom end of the shell 1 at the moment, if the nozzle at the bottom end of the shell 1 is blocked, the ink pressure inside the shell 1 will rise, because the connecting pipe 12 fixedly installed between the pressure cylinder 13 and the shell 1 realizes the communication of the internal spaces of the two, a stress disc 14 is attached to the inner wall of the pressure cylinder 13, a second spring 15 is fixedly connected between the end surface of the stress disc 14 and the inner wall of the pressure cylinder 13, and one end of an inner column 16 is coaxially connected to the inner wall of the pressure cylinder 13, meanwhile, a switch 17 arranged on the end face of the other end of the inner column 16 is positioned at the side of the stress disc 14, the internal ink pressure of the connecting pipe 12 and the pressure cylinder 13 is synchronously increased, the stress disc 14 is pushed to move in the pressure cylinder 13 by using the change of pressure difference, so that the stress disc 14 moves towards the inner column 16, the stress disc 14 compresses the second spring 15, and when the stress disc 14 is contacted with the switch 17 on the inner column 16, the switch 17 sends a starting signal to the air pump 3 through a control system;

referring to fig. 1-5, following the above steps, the air pump 3 sends high pressure air into the space at the top of the housing 1 through the air pipe 4, because the plug body 5 is arranged below the port of the air pipe 4, the plug body 5 is attached to the inner wall of the housing 1, the first spring 6 is fixedly connected between the upper surface of the plug body 5 and the top of the inner wall of the housing 1, the center of the bottom surface of the plug body 5 is vertically connected with the thimble 7, the thimble 7 is slidably arranged through the partition plate 8, the lower end of the thimble 7 is coaxially arranged above the bottom nozzle of the housing 1, at this time, a pressure difference is formed between the upper side and the lower side of the plug body 5, the plug body 5 is pushed to move downwards by the pressure difference, the plug body 5 drives the thimble 7 to move synchronously, so that the bottom end of the thimble 7 is dredged through the bottom nozzle of the housing 1, in the above process, the push block 10 coaxially connected on the side wall of the thimble 7 moves synchronously, the conical push block 10 slides downwards along the inner wall of the shell 1, the guide pillar 9 embedded on the push block 10 in a sliding mode plays a role in guiding and limiting, and the push block 10 can further extrude ink at the bottom of the shell 1, so that the ink can be sprayed out from a dredging nozzle, and the dredging effect is improved.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a glaze pottery 3D nanometer inkjet printing shower nozzle, includes:

the air pump comprises a shell (1) which is fixedly connected to the side wall of a mounting plate (2), wherein one end of an air pipe (4) is fixedly penetrated through the center of the top of the shell (1), the other end of the air pipe (4) is fixedly communicated with an air pump (3), and the air pump (3) is fixedly connected to the mounting plate (2);

it is characterized by also comprising:

the plug body (5) is attached to the inner wall of the shell (1) and coaxially arranged with the inner wall of the shell (1), a first spring (6) is fixedly connected between the upper surface of the plug body (5) and the top of the inner wall of the shell (1), a partition plate (8) is arranged below the plug body (5), and the partition plate (8) is coaxially connected to the inner wall of the shell (1) and used for separating a space;

thimble (7), its upper end is connected perpendicularly in the bottom surface center department of cock body (5), thimble (7) slide run through in baffle (8) set up, and the lower extreme coaxial setting of thimble (7) is in the top of shell (1) bottom spout to baffle (8) below is provided with horizontally transfer line (11), and the port fixed run-through of transfer line (11) is installed on the lateral wall of shell (1) moreover.

2. The glazed ceramic 3D nano inkjet printing head according to claim 1, wherein: baffle (8) are discoid structure, and the laminating is provided with ejector pad (10) on the bottom surface of baffle (8) to the lateral wall laminating setting of ejector pad (10) is in on the inner wall of shell (1), fixed through mounting has thimble (7) of coaxial setting on ejector pad (10).

3. The glazed ceramic 3D nano inkjet printing head according to claim 2, wherein: the ejector pin is characterized in that guide pillars (9) are vertically connected to the bottom surface of the partition plate (8), the two guide pillars (9) are symmetrically distributed on two sides of the ejector pin (7), the ejector block (10) is of a conical structure, a guide hole is formed in the top of the ejector block (10), and the guide pillars (9) are embedded in the guide hole in a sliding mode to form a guide limiting structure.

4. The glazed ceramic 3D nano inkjet printing head according to claim 1, wherein: one end of a connecting pipe (12) is installed on the side wall, far away from the infusion pipe (11), of the shell (1) in a penetrating mode, the other end of the connecting pipe (12) is fixedly arranged in a pressure cylinder (13) in a penetrating mode, and the connecting pipe (12), the infusion pipe (11) and the pressure cylinder (13) are coaxially arranged.

5. The glazed ceramic 3D nano inkjet printing head according to claim 4, wherein: a stress disc (14) is attached to the inner wall of the pressure cylinder (13), and a second spring (15) is fixedly connected between the end face, far away from the connecting pipe (12), of the stress disc (14) and the inner wall of the pressure cylinder (13).

6. The glazed ceramic 3D nano inkjet printing head according to claim 5, wherein: second spring (15) cover is established on the lateral wall of interior post (16), and the one end coaxial coupling of interior post (16) is in on the inner wall of pressure section of thick bamboo (13) to fixed mounting has switch (17) on interior post (16) other end terminal surface, and switch (17) are located moreover the avris of atress dish (14).

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