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A micro-nano carbon far-infrared physiotherapy floor

A micro-nano, far-infrared technology, used in coatings, electrical components, ohmic resistance heating, etc., can solve the problems of limited usage and functionality, low far-infrared functionality, etc. , flexible and strong effect

Active Publication Date: 2018-05-15
浙江康辉木业有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0006] It can be seen from the above-mentioned prior art that far-infrared heating floors mostly use far-infrared substances to treat the base material to make it have far-infrared performance. limited sex

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0028] (1) The PAN-based carbon fiber is used as the warp, the copper-based fiber is used as the weft, and the warp-heavy flat weave is used as the fabric structure, and the weaving forms 250g / cm 2 flexible conductive fabric.

[0029] (2) by weight, add 10 parts of titanate coupling agent and quaternary ammonium salt surfactant in 20 parts of micro-nano-level zinc oxide and magnesium oxide, 15 parts of micro-nano-level graphite powder, Mix and grind, then add 30 parts of butyl etherified urea-formaldehyde resin material, and obtain a far-infrared coating after homogeneous stirring.

[0030] (3) The surface of the flexible conductive base cloth prepared in step (1) is provided with wires and electrodes, and then the far-infrared coating prepared in step (2) is coated first, dried and cured, and then coated with a layer of polyimide The amine film is cured and sealed to obtain a far-infrared heating layer.

[0031] (4) According to the order from top to bottom, the water-resis...

Embodiment 2

[0033] (1) The PAN-based carbon fiber is used as the warp, the silver-based fiber is used as the weft, and the warp-heavy flat weave is used as the fabric structure, and weaving forms 300g / cm 2 flexible conductive fabric.

[0034] (2) In parts by weight, 20 parts of titanate coupling agents and quaternary The ammonium salt surfactant is mixed and ground, and then 40 parts of butyl etherified urea-formaldehyde resin materials are added, and the far-infrared coating is obtained after homogeneous stirring.

[0035] (3) The surface of the flexible conductive base cloth prepared in step (1) is provided with wires and electrodes, and then the far-infrared coating prepared in step (2) is coated first, dried and cured, and then coated with a layer of polyimide The amine film is cured and sealed to obtain a far-infrared heating layer.

[0036] (4) According to the order from top to bottom, the water-resistant and wear-resistant layer, the solid wood surface layer, the temperature con...

Embodiment 3

[0038](1) Use PAN-based carbon fiber as the warp thread, stainless steel fiber as the weft thread, and use warp-heavy flat weave as the fabric structure, weaving to form a 280g / cm 2 flexible conductive fabric.

[0039] (2) In parts by weight, add 15 parts of titanate coupling agent and quaternary ammonium salt surface in 25 parts of micro-nano-level zinc oxide, titanium dioxide and silicon dioxide, 20 parts of micro-nano-level graphite powder The active agent is mixed and ground, and then 35 parts of butyl etherified urea-formaldehyde resin materials are added, and the far-infrared coating is obtained after homogeneous stirring.

[0040] (3) The surface of the flexible conductive base cloth prepared in step (1) is provided with wires and electrodes, and then the far-infrared coating prepared in step (2) is coated first, dried and cured, and then coated with a layer of polyimide The amine film is cured and sealed to obtain a far-infrared heating layer.

[0041] (4) According ...

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Abstract

The invention provides a novel micro-nano carbon far infrared physiotherapy floor and a preparation method thereof. The method comprises the specific operation steps: (1) PAN-based carbon fiber serves as warp, metal fiber serves as weft, warp rib is adopted to serve as a fabric structure, and a flexible conductive fabric is formed through weaving; (2) an additive is added to micro-nano metallic oxide and micro-nano graphite powder, mixing and grinding are carried out, resin material is then added, and a far infrared coating layer is obtained after uniform stirring; (3) a wire and an electrode are arranged on the surface of the flexible conductive fabric, a layer of far infrared coating layer is firstly coated, drying and curing are carried out, a layer of insulated layer is then coated, and a far infrared heating layer is obtained after curing and sealing; and (4) according to an order from top to bottom, a water-resisting and wear-resisting layer, a solid wood surface layer, a temperature control layer, the far infrared heating layer, a high temperature-resisting insulated layer, a reflection layer, and a solid wood bottom layer are cut and laid together, and through heating and compression composition and opening finishing, the micro-nano carbon far infrared physiotherapy floor is formed.

Description

Technical field: [0001] The invention belongs to the technical field of electric heating floors, and in particular relates to a micro-nano carbon far-infrared physiotherapy floor and a preparation method thereof. Background technique: [0002] Since more than 200 years ago, humans have discovered that any object with a temperature higher than zero Kelvin will radiate infrared rays. The wavelength of infrared rays varies with the molecular structure and temperature of the radiator material, and can produce 2.5-25μm. Far-infrared radiation greater than 25 μm. Experiments have found that the far-infrared wavelength is 2.5-25μm, which is a high-energy-carrying wave, which has biomedical effects on the human body, can promote human microcirculation, treat post-illness, cardiovascular disease, waist and leg pain, arthritis, frozen shoulder, cervical spine It has remarkable effects in eliminating and alleviating diseases such as stomach disease and gastrointestinal disease, so it ...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): E04F15/02H05B3/22C09D7/61C09D161/32
CPCY02P20/133
Inventor 徐政涛
Owner 浙江康辉木业有限公司
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