CN2866527Y - Natural energy health care polymer surface cloth - Google Patents

Abstract

The utility model relates to a natural energy health care macromolecule surface fabric material, it mixes in the high molecular polymer and mixes the oxide powder particle that can produce far infrared ray or can produce the anion, utilize processing aid and bridging agent, make far infrared ray and high molecular polymer both adjust its cross-linking density and stir and mix, extrude into the sheet surface fabric material with the running roller of calender with the material that mixes again, add sulphur and make it ripe to cross, again with the hole punch impact intensive bleeder vent on the sheet surface fabric material, cut into appropriate length with this fabric material, and then make and mix the functional oxide powder particle that contains sufficient dose, and the macromolecule surface fabric material that has preferred gas permeability and structural strength, make this fabric material have preferred far infrared radiation rate and permeability, and can be applicable to various articles for use.

Description

Natural energy health care polymer surface cloth

technical field

The utility model relates to a natural energy health-care polymer surface cloth material, especially a non-woven, thin sheet surface cloth material made of high molecular polymer (the high molecular polymer can be rubber or plastic). In addition, a plurality of functional oxide particles are mixed in the high molecular polymer, and a plurality of densely distributed air holes are punched on the cloth material, so as to improve the health care performance, use comfort and durability. And it is fully used in all kinds of people's daily necessities.

Background technique

Generally, traditional far-infrared emitters are obtained from natural ores and metal oxides, mixed with several metal oxides, and calcined at high temperature. The early far-infrared emitting products were mainly in the form of ceramics to extend their product value, but the texture of ceramics is hard, and it is difficult to shape the shape of the product, especially if the general product is applied to the human body, the requirements for compliance are It is quite strict, and it is difficult to apply it to conventional ceramics. For this reason, later on, some operators ground their calcined far-infrared emitters into powder, and then mixed the powder into polyester fibers, and attached them to the cloth by blending or coating, etc., and then It has opened a new era in which human beings apply far-infrared emitters to the human body in large quantities as health care or heat storage and heat preservation applications. However, in the currently known technology, there are still shortcomings and no further breakthroughs can be made, because the ratio of far-infrared rays and fiber blends generally used in the textile industry is about 1:10 or less. If the dosage of far-infrared powders If the proportion is too high, it will easily affect the physical properties of the spinning fiber, which will easily cause fiber brittle fracture and difficulty in post-processing. Therefore, the currently known fibers containing far-infrared powders have a very small dose of far-infrared powder, and if the dose is insufficient, their far-infrared emissivity and permeability are not enough at all, and cannot achieve effective health care or temperature storage. function, its effectiveness is greatly reduced.

Contents of the invention

The purpose of this utility model is to overcome the deficiencies of the prior art, to provide a kind of powder that can effectively increase the dosage of mixed functional oxides, so as to improve the effectiveness of human health care, and can also have better structural strength, which can improve Durability, and improved breathability and comfort energy health surface fabrics and methods for their manufacture.

In order to achieve the above object, the utility model takes the following design scheme:

A natural energy health care polymer surface cloth material, which is mainly a non-woven, thin sheet surface cloth material made of a high molecular polymer, and a plurality of functional oxide powders are mixed in the high molecular polymer, In addition, a plurality of densely distributed ventilation holes are punched on the cloth material.

The particle size of the functional oxide powder is submicron or nanometer.

The functional oxide powder is an oxide powder that can generate far infrared rays.

The functional oxide powder contains Al ₂ O ₃ , or MgO, or ZrO ₂ , or TiO ₂ , or SiO ₂ , or a combination thereof.

The functional oxide powder contains Al ₂ O ₃ , or MgO, or ZrO ₂ , or TiO ₂ , or SiO ₂ , or a combination of Al ₂ O ₃ , MgO, ZrO ₂ , TiO ₂ , and SiO ₂ . Oxide particles are stored in the powder of granite, dolomite, medical stone, serpentine or tourmaline, and the powder of granite, dolomite, medical stone, serpentine or tourmaline The particles are uniformly mixed in the polymer, and the particle size of the granite, dolomite, medical stone, serpentine or tourmaline powder is submicron.

The functional oxide powder is an oxide powder capable of generating far-infrared rays, and the emissivity of the far-infrared rays is above 0.8.

The functional oxide powder is an oxide powder that can generate negative ions.

The functional oxide powder is a photocatalyst.

The high molecular polymer is rubber.

The high molecular polymer is PU, or UP, or Phenol, or NBR, or SBR, and the oxide powder contains SiO ₂ .

The high molecular polymer is Epoxy, and the oxide powder contains SiO ₂ or TiO ₂ .

The high molecular polymer is plastic.

The high molecular polymer is PS, or ABS, or PVC, or PET, or Nylon, or PBT, or TPE, and the oxide powder contains SiO ₂ .

The high molecular polymer is PET, or PP, or Nylon, and the oxide is ZrO ₂ .

It is a non-woven, sheet-like cloth made of high molecular polymer. The high molecular polymer is mixed with a plurality of densely distributed functional oxide particles, and a plurality of A dense air hole, and a cloth layer composed of fibers is pasted on at least one side of the cloth material to form a pad.

Both sides of the cloth material are pasted with a cloth layer composed of fibers, and one of the cloth layers is gauze.

The utility model has the advantages of:

1. The planar cloth material of this utility model is mixed with oxide powders that can generate far infrared rays or negative ions, the oxide powders will not fall off, and the dosage can be easily adjusted. Not only the health care effect is greatly improved, but also it is not easy to damage and durable Excellent sex.

2. The planar cloth material made by the utility model not only has excellent far-infrared rays or negative ion health care functions, but also has a simple manufacturing process and can reduce manufacturing costs.

3. Under the principle of effectively improving the health care effect, the planar cloth material made by the utility model has dense air holes on it and has better air permeability. Sex, and achieve the effect of product optimization.

4. In addition to having higher far-infrared emissivity and health care performance than conventional textiles, the surface cloth material made by the utility model also has sufficient softness and flexibility, and can be fully applied in more A variety of daily necessities, such as mattresses, chair cushions and clothing fabrics and so on.

Description of drawings

Fig. 1 is the three-dimensional schematic diagram of cloth material of the present utility model;

Fig. 2 is a cross-sectional schematic view of the utility model made of a pad cloth with a cloth material;

Fig. 3 is a three-dimensional schematic view of the utility model made of a cloth material as a pad;

Fig. 4 is the schematic flow chart of the method of the present utility model;

Fig. 5 is a simple schematic diagram of the method flow and matching equipment of the present invention.

Detailed ways

Please refer to Fig. 1 to Fig. 3, the cloth structure of the specific embodiment of the present invention is a non-woven, sheet-like cloth made of high molecular polymer (the high molecular polymer can be rubber or plastic) The material 10 is mixed with a plurality of functional oxide particles 11 in the high molecular polymer, and a plurality of dense air holes 12 are punched on the cloth material 10 . Wherein, the functional oxide powder is an oxide powder that can generate far-infrared rays, or an oxide powder that can generate negative ions, or a photocatalyst, such as ZnO, or Al ₂ O ₃ , or MgO, or ZrO ₂ , or TiO ₂ , or SiO ₂ , or a combination thereof, the particle size of the oxide powder can be submicron or nanometer. Furthermore, the functional oxide powder is ZnO, or Al ₂ O ₃ , or MgO, or ZrO ₂ , or TiO ₂ , or SiO ₂ , which is stored in granite, dolomite, medical stone, serpentine or tourmaline powder, and the powder of granite, dolomite, medical stone, serpentine or tourmaline is uniformly mixed in the polymer, and the granite, dolomite, wheat The particle size of meal stone, serpentine or tourmaline powder is submicron. Among them, the radiation rate of far-infrared rays is at least 0.85, that is, the average radiation of 4~15 μm is more than 85%, so that it can achieve a truly effective health care effect on the human body.

Please refer to Fig. 1 to Fig. 3, the utility model can make the aforesaid cloth material into a pad cloth which can be applied to mattresses and chair seat cushions. The cloth material 10 is mixed with a plurality of densely distributed functional oxide particles 11 inside, and a plurality of densely distributed air holes 12 are punched on the planar cloth material 10, and at least one side of the planar cloth material 10 A cloth layer 13,14 composed of fibers is pasted on it. When the utility model was implemented, a cloth layer 13,14 made of fibers could be pasted on both sides of the cloth material 10, and one of the cloth layers could be gauze 13.

In a specific embodiment of the present invention, the polymer can be PU resin, UP resin, phenol resin Phenol, nitrile butadiene resin NBR, or SBR resin, and the oxide is SiO ₂ . If the polymer is epoxy resin Epoxy, and the oxide is SiO ₂ or TiO ₂ .

In the implementation of the utility model embodiment, the polymer can be PS, acrylonitrile-butadiene-styrene resin ABS, polyvinyl chloride PVC, polyethylene terephthalate PET, nylon Nylon, polyparaffin Dibutyl phthalate PBT, or TPE, and the oxide is SiO ₂ . If the polymer is polyethylene terephthalate PET, polypropylene PP, or nylon Nylon, the oxide is ZrO ₂ .

Please refer to Fig. 4 to Fig. 5, the method for making of the present utility model includes:

Prepare 10-50 parts by weight that can produce far-infrared rays, or can produce negative ions, or oxide particles of photocatalyst, and 100 parts by weight of high molecular polymer 100 (such as rubber or plastic);

Combine 1~15 parts by weight of processing aids and bridging agents (bridging agents such as CZ, BZ, EZ, and PZ) in a mixer to adjust the cross-linking density of far-infrared rays and high molecular polymers for stirring and mixing (step A);

Then the mixed material is extruded into a sheet-like cloth material 10 with the roller of the calender (step B);

Add sulfur and make it bridging mature (step E);

Then impact the dense ventilation holes on the sheet surface cloth material 10 with the punching machine 15 (step G); and

Then the cloth material is cut to an appropriate length, and the manufacture is completed (step H).

Wherein, in the above-mentioned manufacturing process of the present invention, when the calender presses out the sheet-like cloth material (step B), a layer of anti-sticking cloth layer (step C) can be put on the first surface of the cloth material to avoid When the cloth is bundled, the overlapping parts will stick to each other, and the anti-stick cloth layer will be removed until the cloth is matured by adding sulfur and bridging. Furthermore, when the calender is extruding the sheet-like cloth material, a layer of gauze may be covered on the second surface of the cloth material (step D) to form a protective layer. In addition, in the above-mentioned process, after the cloth material is impacted and densely covered with air holes, a layer of cloth is pasted on the first surface of the cloth (step F). The face cloth can be a functional cloth, such as anti-mite and antibacterial, Moisture-wicking fabric.

The foregoing is a feasible embodiment of the present utility model, and is not intended to limit the patent scope of the present utility model. For example, any equivalent implementation based on the content, features and spirit of the following patent scope and its other changes are all Should be included in the patent scope of the present utility model.

Claims (6)

1, the planar cloth material of a kind of natural energy health care macromolecule is characterized in that:

It is the planar cloth material made from high molecular polymer of non-braiding, thin slice, is provided with a plurality of densely covered air-vents in this cloth material upper punch.

2, the planar cloth material of natural energy health care macromolecule according to claim 1, it is characterized in that: this high molecular polymer is a rubber.

3, the planar cloth material of natural energy health care macromolecule according to claim 1, it is characterized in that: this high molecular polymer is plastics.

4, the planar cloth material of natural energy health care macromolecule according to claim 1, it is characterized in that: this high molecular polymer is PET, or PP, or Nylon.

5, the planar cloth material of natural energy health care macromolecule according to claim 1 is characterized in that: this cloth material is sticked on the one side at least and one forms shield with fibrous layer of cloth.

6, the planar cloth material of natural energy health care macromolecule according to claim 5 is characterized in that: this cloth material two sides respectively is sticked one with fibrous layer of cloth, and wherein a layer of cloth is a gauze.

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