CN213676009U

CN213676009U - LED-UV curing device for battery tin printing

Info

Publication number: CN213676009U
Application number: CN202021450488.5U
Authority: CN
Inventors: 余康; 梁永明; 文慧
Original assignee: Hangzhou Cofco Pack Co ltd
Current assignee: Hangzhou Cofco Pack Co ltd
Priority date: 2020-07-21
Filing date: 2020-07-21
Publication date: 2021-07-13
Anticipated expiration: 2030-07-21

Abstract

The utility model discloses a LED-UV curing device for battery tin printing, relating to the technical field of battery tin printing; the LED-UV light source is arranged on the other side of the shell and faces the inside of the shell; the unidirectional air outlet comprises an air pipe, a guide groove, a cover plate, a tubular guide sleeve, a spring and a plurality of air outlet holes, wherein one end of the air pipe is fixedly connected to the shell, the guide groove is positioned at one end of the air pipe, which is far away from the shell, the cover plate is covered at one end of the air pipe, which is far away from the shell, the tubular guide sleeve is connected in the guide groove in a sliding manner, the spring is positioned in the guide groove and is used for applying force towards one side of; one end of the guide sleeve is fixedly connected to the cover plate. The one-way air outlet plays a dustproof role, preheating is not needed when an LED-UV light source is used, meanwhile, the curing efficiency is more efficient, a fan is added, and heat dissipation is improved.

Description

LED-UV curing device for battery tin printing

Technical Field

The utility model belongs to the technical field of battery tin printing, in particular to a LED-UV solidification equipment for battery tin printing.

Background

When the battery is subjected to metal printing, a coating with excellent processing resistance and LED ink are adopted, a curing device is required to be used for curing the ink on the surface of the battery, and the traditional curing method adopts a high-pressure mercury lamp for curing, so that the curing efficiency is low.

Disclosure of Invention

The utility model aims at overcoming the shortcoming that prior art solidification is inefficient, propose a LED-UV solidification equipment for battery tin printing, solidification efficiency is high.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an LED-UV curing device for battery tin printing comprises a conveyor belt for conveying materials, a shell positioned above the conveyor belt, a circuit board positioned in the shell, an LED-UV light source positioned on the lower side of the circuit board, a light-transmitting plate positioned on the lower side of the shell, a one-way air outlet positioned on one side of the shell and facing the outer side of the shell, a fan positioned on the other side of the shell and facing the inner part of the shell, and dustproof cloth positioned on one side of the fan far away from the shell; the unidirectional air outlet comprises an air pipe, a guide groove, a cover plate, a tubular guide sleeve, a spring and a plurality of air outlet holes, wherein one end of the air pipe is fixedly connected to the shell, the guide groove is positioned at one end of the air pipe, which is far away from the shell, the cover plate is covered at one end of the air pipe, which is far away from the shell, the tubular guide sleeve is connected in the guide groove in a sliding manner, the spring is positioned in the guide groove and is used for applying force towards one side of; one end of the guide sleeve is fixedly connected to the cover plate. The one-way air outlet plays a dustproof role, preheating is not needed when an LED-UV light source is used, meanwhile, the curing efficiency is more efficient, a fan is added, and heat dissipation is improved. In addition, a refrigerating pipe is arranged near the fan, so that the effect of blowing cold air is achieved, and the cooling effect is improved.

Preferably, the lower side of the guide sleeve is provided with a plurality of air outlet holes, one side of the circuit board is fixedly connected with a plurality of first heat-conducting fins, and one end, far away from the circuit board, of each first heat-conducting fin penetrates through the shell and then is located on the lower side of the guide sleeve. The wind that the exhaust vent came out blows first conducting strip, takes away the heat on the first conducting strip.

Preferably, the other side of the circuit board is fixedly connected with a plurality of second heat-conducting fins, one end, far away from the circuit board, of each second heat-conducting fin penetrates through the shell and then is fixedly connected with a third heat-conducting fin, the lower end of each third heat-conducting fin is fixedly connected to the corresponding second heat-conducting fin, and the third heat-conducting fins are located on one side, far away from the shell, of the fan. The wind around the fan passes through the third heat-conducting fin to take away the heat on the third heat-conducting fin.

Preferably, the dustproof cloth is detachably connected with the shell. The dustproof cloth is convenient to clean.

Preferably, the light-transmitting plate is detachably connected to the housing. The light-transmitting plate is convenient to clean.

Preferably, the first heat conducting strip, the second heat conducting strip and the third heat conducting strip are made of copper. The thermal conductivity is good.

Preferably, the cross section of the guide sleeve is circular, and the air outlet holes are uniformly distributed along the port of the guide sleeve.

The utility model has the advantages that: the utility model provides a LED-UV solidification equipment for battery seal iron, the solidification is efficient. The one-way air outlet plays a dustproof role, preheating is not needed when an LED-UV light source is used, meanwhile, the curing efficiency is more efficient, a fan is added, and heat dissipation is improved.

Drawings

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

FIG. 2 is a schematic view of the fan in operation;

fig. 3 is a schematic view of the guide sleeve and the cover plate.

In the figure: the LED-UV light source comprises a conveyor belt 1, a shell 2, a circuit board 3, an LED-UV light source 4, a light-transmitting plate 5, a one-way air outlet 6, a fan 7, dustproof cloth 8, an air pipe 9, a guide groove 10, a cover plate 11, a guide sleeve 12, a spring 13, an air outlet hole 14, a first heat-conducting fin 15, a second heat-conducting fin 16 and a third heat-conducting fin 17.

Detailed Description

The invention will be further explained in detail with reference to the drawings and the following detailed description:

example (b):

referring to fig. 1 to 3, an LED-UV curing device for battery tin printing comprises a conveyor belt 1 for conveying materials, a housing 2 located above the conveyor belt 1, a circuit board 3 located in the housing 2, an LED-UV light source 4 located on the lower side of the circuit board 3, a light-transmitting plate 5 located on the lower side of the housing 2, a one-way air outlet 6 located on one side of the housing 2 and facing the outside of the housing 2, a fan 7 located on the other side of the housing 2 and facing the inside of the housing 2, and a dustproof cloth 8 located on one side of the fan 7 and away from the housing 2. The dustproof cloth 8 is detachably connected with the shell 2. The light-transmitting plate 5 is detachably connected to the housing 2.

The one-way air outlet 6 comprises an air pipe 9, one end of which is fixedly connected with the shell 2, a guide groove 10, a cover plate 11, a tubular guide sleeve 12, a spring 13 and a plurality of air outlet holes 14, wherein the guide groove 10 is positioned at one end of the air pipe 9 far away from the shell 2, the cover plate 11 covers one end of the air pipe 9 far away from the shell 2, the guide sleeve 12 is connected in the guide groove 10 in a sliding mode, the spring 13 is positioned in the guide groove 10 and used for applying force towards one side of the shell 2 to the guide sleeve 12; one end of the guide sleeve 12 is fixedly connected to the cover plate 11. The cross section of the guide sleeve 12 is circular, and the air outlet holes 14 are uniformly distributed along the port of the guide sleeve 12.

The lower side of the guide sleeve 12 is provided with a plurality of air outlet holes 14, one side of the circuit board 3 is fixedly connected with a plurality of first heat-conducting fins 15, and one end, far away from the circuit board 3, of each first heat-conducting fin 15 penetrates through the shell 2 and then is located on the lower side of the guide sleeve 12.

The other side of the circuit board 3 is fixedly connected with a plurality of second heat-conducting fins 16, one end, far away from the circuit board 3, of each second heat-conducting fin 16 penetrates through the shell 2 and then is fixedly connected with a third heat-conducting fin 17, the lower end of each third heat-conducting fin 17 is fixedly connected to the corresponding second heat-conducting fin 16, and the third heat-conducting fins 17 are located on one side, far away from the shell 2, of the fan 7.

The first heat conduction sheet 15, the second heat conduction sheet 16, and the third heat conduction sheet 17 are made of copper.

Principles of embodiments;

the LED-UV light source 4 emits light downwards to irradiate the materials on the conveyor belt 1, so that the paint on the surfaces of the materials is cured, and the curing efficiency is high.

The LED-UV light source 4 generates a large amount of heat inside the housing 2 while emitting light, in order to well lower the temperature of the housing 2, thereby enabling stable operation for a long time.

The fan 7 operates to blow outside air into the shell 2, the air pressure in the shell 2 becomes high, the spring 13 extends, the cover plate 11 and the air pipe 9 are separated, the guide sleeve 12 moves towards one side far away from the shell 2, and the air in the shell 2 is discharged from the air outlet 14, so that the purpose of heat dissipation is achieved.

The dust cloth 8 can reduce dust in the housing 2, and when the fan 7 is not operated, the cover plate 11 covers the air duct 9 to prevent external dust from entering the housing 2.

The heat of the circuit board 3 is conducted to the first heat conductive sheet 15, the second heat conductive sheet 16, and the third heat conductive sheet 17.

When the fan 7 is operated, wind passes through the third heat-conducting strip 17, and heat of the third heat-conducting strip 17 is taken away.

The air exiting the air outlet 14 blows the first heat-conducting strip 15, thereby taking away the heat of the first heat-conducting strip 15.

Claims

1. An LED-UV curing device for battery tin printing is characterized by comprising a conveyor belt for conveying materials, a shell positioned above the conveyor belt, a circuit board positioned in the shell, an LED-UV light source positioned on the lower side of the circuit board, a light-transmitting plate positioned on the lower side of the shell, a one-way air outlet positioned on one side of the shell and facing the outer side of the shell, a fan positioned on the other side of the shell and facing the inner part of the shell, and dustproof cloth positioned on one side of the fan far away from the shell;

the unidirectional air outlet comprises an air pipe, a guide groove, a cover plate, a tubular guide sleeve, a spring and a plurality of air outlet holes, wherein one end of the air pipe is fixedly connected to the shell, the guide groove is positioned at one end of the air pipe, which is far away from the shell, the cover plate is covered at one end of the air pipe, which is far away from the shell, the tubular guide sleeve is connected in the guide groove in a sliding manner, the spring is positioned in the guide groove and is used for applying force towards one side of;

one end of the guide sleeve is fixedly connected to the cover plate.

2. The LED-UV curing apparatus for battery tinplate of claim 1, wherein the guiding sleeve has a plurality of air outlets on the lower side thereof, and a plurality of first heat-conducting fins are fixed to one side of the circuit board, and the end of the first heat-conducting fins away from the circuit board passes through the housing and then is located on the lower side of the guiding sleeve.

3. The LED-UV curing apparatus for battery iron printing according to claim 2, wherein a plurality of second heat conducting strips are fixedly connected to the other side of the circuit board, a third heat conducting strip is fixedly connected to one end of the second heat conducting strip away from the circuit board after the end of the second heat conducting strip passes through the housing, the lower end of the third heat conducting strip is fixedly connected to the second heat conducting strip, and the third heat conducting strip is located on one side of the fan away from the housing.

4. The LED-UV curing apparatus for battery tinplate of claim 1, wherein the dust cloth is removably attached to the housing.

5. The LED-UV curing apparatus for battery tinplate of claim 1, wherein the light-transmitting plate and the housing are removably connected.

6. The LED-UV curing apparatus for battery iron printing according to claim 3, wherein the first, second and third heat-conducting sheets are made of copper.

7. The LED-UV curing apparatus for battery tinplate of claim 1, wherein the cross section of the guiding sleeve is circular, and the air outlets are uniformly distributed along the end of the guiding sleeve.