Far-infrared carbon-based composite electrothermal ink and its preparation method and application

An electrothermal ink and far-infrared technology, applied in the field of ink, can solve the problems of insufficient far-infrared radiation rate, weak influence on the human body, low effect of physical therapy and health care, etc., and achieve the effect of simple preparation process, low cost and wide source

Active Publication Date: 2016-06-01
GUANGDONG JUNFENG BFS TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0004] However, the carbon-based electrothermal ink of the prior art, after being energized, at a certain temperature, the far-infrared radiation rate is not high enough, the effect on the human body is weak, the effect of physical therapy and health care is low, and the temperature required to produce far-infrared radiation is relatively high. Generally, it needs to be above 150°C to have strong radiation, and it does not have the ability to release hydroxyl anions (H 3 o 2 - ), antibacterial, antibacterial and air purifying functions

Method used

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  • Far-infrared carbon-based composite electrothermal ink and its preparation method and application

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Experimental program
Comparison scheme
Effect test

Embodiment 1

[0029] The tourmaline powder is added with an appropriate amount of water, stirred, ball milled and superfinely ground, and finally spray-dried to form a composite oxide powder with a particle size distribution of 0.1-2.0 μm.

[0030] figure 1 It is a schematic flow chart of the preparation method of the far-infrared carbon-based composite electrothermal ink of the present invention, as figure 1 As shown, take 2 g of the above composite oxide powder, add 4 g of isophorone, and stir rapidly until the powder is uniformly dispersed to form a composite oxide dispersion.

[0031] Add the uniformly dispersed composite oxide dispersion into 92g of carbon-based electrothermal ink, and stir at a high speed at a speed of 2500-3000 rpm, mix thoroughly for 20-30 minutes, and then grind in a grinder for 3-5 Repeat until the system is uniform and stable, and the far-infrared carbon-based composite electrothermal ink of the present invention is obtained. In this embodiment, the parameters ...

Embodiment 2

[0034] Mix tourmaline powder and Sibin pumice powder at a ratio of 2:1, add an appropriate amount of water, carry out stirring, ball milling and ultrafine grinding, and finally spray dry to make a composite oxide powder with a particle size of 0.1-2.0 μm body.

[0035] Take 15 g of the above composite oxide powder, add 40 g of isophorone, and stir rapidly until the powder is uniformly dispersed to form a composite oxide dispersion.

[0036] Add the uniformly dispersed composite oxide dispersion into 945g carbon-based electrothermal ink, and stir at a high speed at a speed of 2500-3000 rpm, mix thoroughly for 20-30 minutes, and then place it in a grinder for 3-5 minutes. Repeat until the system is uniform and stable, and the far-infrared carbon-based composite electrothermal ink of the present invention is obtained. In this embodiment, the parameters of the carbon-based electrothermal ink used as raw materials are: viscosity 300P, solid content 78%, resistivity 40Ω / sq.

[003...

Embodiment 3

[0039] Mix seagull stone powder, Sibin pumice powder and tourmaline powder in a ratio of 2:2:1, add appropriate amount of water, stir, ball mill and ultrafine grind, and finally spray dry to make a particle size of 0.1~ 2.0μm composite oxide powder.

[0040] Take 50 g of the above composite oxide powder, add 50 g of isophorone, and stir rapidly until the powder is uniformly dispersed to form a composite oxide dispersion.

[0041] Add the uniformly dispersed composite oxide dispersion into 900g carbon-based electrothermal ink, stir at a high speed at a speed of 2500-3000 rpm, mix thoroughly for 20-30 minutes, and then place it in a grinder for 3-5 minutes. Repeat until the system is uniform and stable, and the far-infrared carbon-based composite electrothermal ink of the present invention is obtained. In this embodiment, the parameters of the carbon-based electrothermal ink used as raw materials are: viscosity 300P, solid content 78%, resistivity 40Ω / sp.

[0042] After testin...

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Abstract

The invention provides a far-infrared carbon composite electric heating ink, and a preparation method and application. The far-infrared carbon composite electric heating ink provided by the invention comprises the following components by mass percent: 1-20% of composite oxide powder, 1-5% of diluent and 75-98% of carbon electric heating ink. The far-infrared carbon composite electric heating ink prepared by the method has an enhanced electric heating function; an ink system is uniform and stable, and can be applied to a far-infrared electric heating product with the enhanced electric heating function.

Description

technical field [0001] The invention relates to an ink technology, in particular to a far-infrared carbon-based composite electrothermal ink and its preparation method and application. Background technique [0002] Carbon-based electrothermal ink has good adhesion on phenolic paper board, epoxy glass fiber board, polyethylene terephthalate (PET) film board and flexible board, and has excellent printability, durability Heat resistance, moisture resistance and stable heat generation, so it is widely used in far-infrared drying ovens, incubators, electric blankets, sauna rooms, circuit boards, electric floor heating panels and greenhouse electric heating and other fields. [0003] At present, in the application of carbon-based electrothermal ink in far-infrared radiation, the principle is that when the carbon-based electrothermal ink is energized, the carbon powder emits far-infrared light of 8-15 μm to generate far-infrared radiation, and the spectrum of 8-15 μm Approximating...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): C09D11/03
Inventor 范广宏何琪任明伟赵春英陈险峰陈俊岭
Owner GUANGDONG JUNFENG BFS TECH
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