CN210161602U - Use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent stifled first device - Google Patents

Abstract

The utility model provides an use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent blocking head device relates to 3D and prints technical field. This use high temperature resistant high molecular polymer's 3D printing shower nozzle prevents choke plug device, including fixing device, cooling device and installation device all are located fixing device's inside, and installation device's bottom is equipped with cooling device, and fixing device includes the mounting panel, and the dead ahead fixed mounting of mounting panel has the pivot. This use high temperature resistant high molecular polymer's 3D print nozzle anti-clogging device, add water to the water storage tank inside through the water inlet, it is intraductal to utilize water delivery pump to transport the inside water of water storage tank to the cooling jacket of printing block surface winding through the aqueduct, the water that utilizes the inside circulation of cooling jacket dispels the heat to the printing block, the inside water of cooling jacket flows inside the heating panel through the connecting tube, utilize the fin to dispel the heat to the heating panel, utilize the back flow to lead the water after the condensation back to in the water storage tank.

Description

Use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent stifled first device

Technical Field

The utility model relates to a 3D prints technical field, specifically is an use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent stifled first device.

Background

3D printing is one of the rapid prototyping technologies, which is a technology for constructing an object by using an adhesive material such as powdered metal or plastic and the like and by using a digital model file as a base and by using a layer-by-layer printing mode, and the 3D printing is usually realized by using a digital technical material printer. The method is often used for manufacturing models in the fields of mold manufacturing, industrial design and the like, and is gradually used for directly manufacturing some products, and parts printed by the technology are already available.

The printing shower nozzle of 3D printer that uses now is blockked up by printing the raw materials easily, so urgently need a 3D who uses high temperature resistant high molecular polymer to print shower nozzle and prevent stifled first device.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model discloses try to overcome above defect, consequently the utility model provides an use high temperature resistant high polymer's 3D to print shower nozzle and prevent blocking head device to reached and reduced the effect that the printing shower nozzle is blockked up.

(II) technical scheme

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides an use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent stifled first device, includes fixing device, cooling device and installation device all are located fixing device's inside, installation device's bottom is equipped with cooling device.

The fixing device comprises a mounting plate, a rotating shaft is fixedly mounted right in front of the mounting plate, a rotating block is sleeved on the surface of the rotating shaft, a spring is fixedly mounted at the bottom of the rotating block, and the bottom of the spring is fixedly connected with the mounting plate.

The cooling device comprises a water inlet, a water storage tank is communicated with the bottom of the water inlet, a water delivery pump is fixedly mounted inside the water storage tank, an output end of the water delivery pump is communicated with a water guide pipe, one end, away from the water delivery pump, of the water guide pipe is communicated with a cooling sleeve, one end, away from the water guide pipe, of the cooling sleeve is communicated with a connecting pipe, one end, away from the cooling sleeve, of the connecting pipe is communicated with a heat dissipation plate, one end, away from the connecting pipe, of the heat dissipation plate is communicated with a return pipe, and one end, away from the.

The mounting device is including printing the piece, the inside cover of printing the piece is equipped with the seal ink shower nozzle, the top fixed mounting of seal ink shower nozzle has the connecting rod, the surperficial threaded connection of connecting rod has the connecting block, and the top of connecting rod is equipped with the mediation pole, the right side of mediation pole is equipped with the gear, the output fixed mounting of the dead astern side of gear and motor.

Furthermore, the right side of the heat dissipation plate is fixedly connected with the mounting plate, and the left side of the heat dissipation plate is fixedly connected with the radiating fins.

Further, the radiating fin is made of metal aluminum alloy, and a radiating hole is formed in the left side of the radiating fin.

Furthermore, the top of the rotating block is fixedly provided with a heat dissipation block, and the top of the heat dissipation block is provided with an air duct.

Further, the ink jet head is in threaded connection with the printing block through a connecting rod, and a cooling sleeve is sleeved on the surface of the printing block.

Further, the surface and the mounting panel fixed connection of connecting block, the right side and the water storage tank fixed connection of mounting panel.

Furthermore, the right side of the dredging rod is meshed with the gear through teeth, and the right rear part of the motor is fixedly connected with the mounting plate.

(III) advantageous effects

The utility model provides a pair of use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent blocking head device. The method has the following beneficial effects:

1. this use high temperature resistant high molecular polymer's 3D print nozzle anti-clogging device, add water to the water storage tank inside through the water inlet, it is intraductal to utilize water delivery pump to transport the inside water of water storage tank to the cooling jacket of printing block surface winding through the aqueduct, the water that utilizes the inside circulation of cooling jacket dispels the heat to the printing block, the inside water of cooling jacket flows inside the heating panel through the connecting tube, utilize the fin to dispel the heat to the heating panel, utilize the back flow to lead the water after the condensation back to in the water storage tank.

2. This use high temperature resistant high polymer's 3D print shower nozzle and prevent blocking head device utilizes the motor to drive the gear and rotates, makes gear left side meshed's mediation pole up-and-down motion, utilizes the conduction tube at connecting rod internal motion to dredge the seal ink shower nozzle.

Drawings

FIG. 1 is a front view of the three-dimensional structure of the present invention;

fig. 2 is a schematic structural diagram of the present invention.

In the figure: the device comprises a fixing device 1, a mounting plate 101, a rotating shaft 102, a rotating block 103, a spring 104, a cooling device 2, a water inlet 201, a water storage tank 202, a water delivery pump 203, a water guide pipe 204, a cooling sleeve 205, a connecting pipe 206, a heat dissipation plate 207, a heat dissipation plate 208, a return pipe 209, a heat dissipation block 210, an air duct 211, a mounting device 3, a printing block 301, a printing nozzle 302, a connecting rod 303, a connecting block 304, a dredging rod 305, a gear 306 and a motor 307.

Detailed Description

According to the utility model discloses an in the first aspect, the utility model provides an use high temperature resistant high polymer's 3D to print shower nozzle anti-clogging device, as shown in fig. 1-2, including fixing device 1, cooling device 2 and installation device 3 all are located fixing device 1's inside, and installation device 3's bottom is equipped with cooling device 2.

In this embodiment, the fixing device 1 includes a mounting plate 101, a rotating shaft 102 is fixedly mounted right in front of the mounting plate 101, a rotating block 103 is sleeved on the surface of the rotating shaft 102, a heat dissipation block 210 is fixedly mounted on the top of the rotating block 103, an air groove 211 is formed in the top of the heat dissipation block 210, and a spring 104 is fixedly mounted on the bottom of the rotating block 103.

Preferably, the bottom of the spring 104 is fixedly connected to the mounting plate 101, and the spring 104 is an elastic member with a uniform elastic curve, and has good controllability.

In this embodiment, the cooling device 2 includes a water inlet 201, a water storage tank 202 is communicated with the bottom of the water inlet 201, a water delivery pump 203 is fixedly installed inside the water storage tank 202, an output end of the water delivery pump 203 is communicated with a water conduit 204, one end of the water conduit 204 far away from the water delivery pump 203 is communicated with a cooling jacket 205, one end of the cooling jacket 205 far away from the water conduit 204 is communicated with a connecting pipe 206, one end of the connecting pipe 206 far away from the cooling jacket 205 is communicated with a heat dissipation plate 207, the right side of the heat dissipation plate 207 is fixedly connected with a mounting plate 101, the left side of the heat dissipation plate 207 is fixedly connected with a heat dissipation fin 208, water is added into the water storage tank 202 through the water inlet 201, the water inside the water storage tank is transported into the cooling jacket 205 wound on the surface of the printing block 301 through the water conduit 204 by the water delivery pump 203, the printing block 301 is dissipated by the, the heat radiation plate 207 radiates heat by the heat radiation fins 208, and the condensed water is returned to the water tank 202 by the return pipe 209.

Preferably, the heat sink 208 is made of metal aluminum alloy, the left side of the heat sink 208 is provided with a heat dissipation hole, one end of the heat dissipation plate 207, which is far away from the connection pipe 206, is communicated with a return pipe 209, and one end of the return pipe 209, which is far away from the heat dissipation plate 207, is communicated with the water storage tank 202.

In this embodiment, the mounting device 3 includes a printing block 301, the inside of the printing block 301 is sleeved with an ink jet head 302, the ink jet head 302 is in threaded connection with the printing block 301 through a connecting rod 303, the surface of the printing block 301 is sleeved with a cooling sleeve 205, and the top of the ink jet head 302 is fixedly mounted with the connecting rod 303.

Further, the surface of the connecting rod 303 is in threaded connection with a connecting block 304, the surface of the connecting block 304 is fixedly connected with the mounting plate 101, the right side of the mounting plate 101 is fixedly connected with the water storage tank 202, a dredging rod 305 is arranged at the top of the connecting rod 303, the right side of the dredging rod 305 is meshed with the gear 306 through teeth, the right back of the motor 307 is fixedly connected with the mounting plate 101, and the right side of the dredging rod 305 is provided with the gear 306.

Preferably, the right back of the gear 306 is fixedly installed with the output end of the motor 307, the input end of the motor 307 is electrically connected with a mains power grid through a frequency converter, the motor 307 drives the gear 306 to rotate, the dredging rod 305 engaged with the left side of the gear 306 moves up and down, and the conduction pipe moves inside the connecting rod 303, so that the ink jet head 302 is dredged.

The working principle is as follows: during the use, add water to water storage tank 202 through water inlet 201 inside, utilize water delivery pump 203 with the inside water of water storage tank to pass through aqueduct 204 and transport to printing block 301 winding cooling jacket 205 in the surface, the inside water that circulates of cooling jacket 205 dispels the heat to printing block 301, the inside water of cooling jacket 205 flows inside heating panel 207 through connecting pipe 206, utilize fin 208 to dispel the heat to heating panel 207, utilize the back flow pipe 209 to lead the water after the condensation back to water storage tank 202 in, utilize motor 307 to drive gear 306 and rotate, make gear 306 left side meshing's dredge bar 305 up-and-down motion, utilize the conduction pipe to move inside connecting rod 303, thereby dredge printing ink shower nozzle 302.

In summary, according to the 3D print head anti-clogging device using the high temperature resistant high molecular polymer, water is added into the water storage tank 202 through the water inlet 201, the water in the water storage tank is transported into the cooling sleeve 205 wound on the surface of the print block 301 through the water conduit 204 by the water delivery pump 203, the print block 301 is radiated by the water circulating inside the cooling sleeve 205, the water in the cooling sleeve 205 flows into the heat radiation plate 207 through the connecting pipe 206, the heat radiation plate 207 is radiated by the heat radiation fin 208, and the condensed water is guided back into the water storage tank 202 by the return pipe 209.

In addition, according to the 3D printing nozzle anti-clogging device using the high temperature resistant high molecular polymer, the motor 307 drives the gear 306 to rotate, so that the dredging rod 305 engaged with the left side of the gear 306 moves up and down, and the conduction pipe moves inside the connecting rod 303, thereby dredging the printing ink nozzle 302.

Claims (7)

1. The utility model provides an use high temperature resistant high molecular polymer's 3D to print shower nozzle and prevent stifled first device, includes fixing device (1), cooling device (2) and installation device (3), its characterized in that: the cooling device (2) and the mounting device (3) are both positioned in the fixing device (1), and the cooling device (2) is arranged at the bottom of the mounting device (3);

the fixing device (1) comprises a mounting plate (101), a rotating shaft (102) is fixedly mounted right in front of the mounting plate (101), a rotating block (103) is sleeved on the surface of the rotating shaft (102), a spring (104) is fixedly mounted at the bottom of the rotating block (103), and the bottom of the spring (104) is fixedly connected with the mounting plate (101);

the cooling device (2) comprises a water inlet (201), the bottom of the water inlet (201) is communicated with a water storage tank (202), a water delivery pump (203) is fixedly installed inside the water storage tank (202), the output end of the water delivery pump (203) is communicated with a water guide pipe (204), one end, far away from the water delivery pump (203), of the water guide pipe (204) is communicated with a cooling sleeve (205), one end, far away from the water guide pipe (204), of the cooling sleeve (205) is communicated with a connecting pipe (206), one end, far away from the cooling sleeve (205), of the connecting pipe (206) is communicated with a heat dissipation plate (207), one end, far away from the connecting pipe (206), of the heat dissipation plate (207) is communicated with a return pipe (209), and one end, far away from the heat dissipation plate (207), of the;

installation device (3) are including printing piece (301), the inside cover of printing piece (301) is equipped with printing ink shower nozzle (302), the top fixed mounting of printing ink shower nozzle (302) has connecting rod (303), the surface threaded connection of connecting rod (303) has connecting block (304), and the top of connecting rod (303) is equipped with dredge pole (305), the right side of dredge pole (305) is equipped with gear (306), the output fixed mounting of gear (306) dead astern and motor (307).

2. The 3D printing nozzle anti-blocking device applying the high-temperature-resistant high-molecular polymer according to claim 1, characterized in that: the right side of the heat dissipation plate (207) is fixedly connected with the mounting plate (101), and the left side of the heat dissipation plate (207) is fixedly connected with a heat dissipation fin (208).

3. The 3D printing nozzle anti-blocking device applying the high-temperature-resistant high-molecular polymer according to claim 2, characterized in that: the radiating fin (208) is made of metal aluminum alloy, and radiating holes are formed in the left side of the radiating fin (208).

4. The 3D printing nozzle anti-blocking device applying the high-temperature-resistant high-molecular polymer according to claim 1, characterized in that: the top of the rotating block (103) is fixedly provided with a heat dissipation block (210), and the top of the heat dissipation block (210) is provided with an air groove (211).

5. The 3D printing nozzle anti-blocking device applying the high-temperature-resistant high-molecular polymer according to claim 1, characterized in that: the ink jet head (302) is in threaded connection with the printing block (301) through a connecting rod (303), and a cooling sleeve (205) is sleeved on the surface of the printing block (301).

6. The 3D printing nozzle anti-blocking device applying the high-temperature-resistant high-molecular polymer according to claim 1, characterized in that: the surface of the connecting block (304) is fixedly connected with the mounting plate (101), and the right side of the mounting plate (101) is fixedly connected with the water storage tank (202).

7. The 3D printing nozzle anti-blocking device applying the high-temperature-resistant high-molecular polymer according to claim 1, characterized in that: the right side of the dredging rod (305) is meshed with the gear (306) through teeth, and the right rear part of the motor (307) is fixedly connected with the mounting plate (101).

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