CN111700321A - Method for manufacturing negative oxygen ion mask - Google Patents

Abstract

The invention provides a method for manufacturing a negative oxygen ion mask, which comprises the following core raw materials in percentage by weight: 10 parts of high-purity germanite, 5 parts of cerium oxide, 40 parts of high-purity tourmaline, 10 parts of conductive titanium dioxide, 5 parts of volcanic rock, 5 parts of medical stone, 10 parts of neodymium iron boron, 2 parts of rare earth zirconium, 1 part of rare earth lanthanum, 5 parts of cerium oxide, 1 part of rare earth terbium and 1 part of rare earth ytterbium; 2. the invention has the beneficial effects that: according to the negative oxygen ion mask, the negative oxygen ion raw pulp is implanted into the mask, so that high-concentration negative oxygen ions can be released, all viruses and bacteria harmful to human bodies are positive charges, and the viruses and the bacteria can be automatically neutralized when encountering the negative oxygen ions, so that the negative oxygen ion mask has the functions of removing formaldehyde, resisting bacteria and preventing haze. The negative oxygen ion mask can effectively resist bacteria and haze and purify the air breathed by a wearer after being used for a long time.

Description

Method for manufacturing negative oxygen ion mask

Technical Field

The technology belongs to the technical field of health care, and relates to a manufacturing method of a negative oxygen ion mask.

Background

With the appearance of haze and the novel coronavirus which is outbreaked in 2020, a large number of people suffer great pain, and simultaneously immeasurable economic loss is caused to various industries. Although the conventional mask has a certain protection effect, the quality problem of the breathing air cannot be effectively improved.

In view of the above, the invention discloses a negative oxygen ion mask, wherein the negative oxygen ion raw pulp is implanted into the mask, so that high-concentration negative oxygen ions can be released, all viruses and bacteria harmful to human bodies are positive charges, and the viruses and the bacteria can be automatically neutralized when encountering the negative oxygen ions, so that the negative oxygen ion mask has the functions of removing formaldehyde, resisting bacteria and preventing haze.

Disclosure of Invention

The invention provides a manufacturing method of a negative oxygen ion mask, which improves the structure of the mask, designs a movable multilayer negative oxygen ion filter chip, enables the mask to be repeatedly used by washing, simultaneously perfectly melts a negative oxygen ion material into high-grade cotton cloth, enables the mask to release high-concentration negative oxygen ions for a long time, and enables bacteria and viruses to be positive charges, and the negative oxygen ions in the negative oxygen ion mask to be automatically neutralized once meeting. Therefore, the negative oxygen ion mask can prevent various virus infections and effectively protect and repair respiratory tracts after being used for a long time.

In order to achieve the purpose, the invention adopts the following technical scheme:

1. the negative oxygen ion raw stock is prepared by a special technology, so that the negative oxygen ion raw stock is non-toxic, harmless and free of radiation pollution;

2. placing the original pulp of negative oxygen ions on high-grade cotton cloth fabric to enable the original pulp to release negative oxygen ions efficiently;

3. through improving gauze mask inner structure, increase filter chip, make the gauze mask can the washing use repeatedly to let the anti-bacterial antifog haze function and the air purification function obtain the performance of maximize.

The beneficial effect of this patent technique lies in:

1. through the effect of negative oxygen ion to and N95 melt-blown cloth and non-woven fabrics, can effectively resist the antifog haze of fungus, and purify the respiratory air of wearer.

2. Through improving gauze mask inner structure, increase filter chip, make the gauze mask can the washing use repeatedly to let the anti-bacterial antifog haze function and the air purification function obtain the performance of maximize, greatly reduced consumer's use cost simultaneously.

Drawings

FIG. 1 is a flow chart of the preparation of the negative oxygen ion raw stock.

FIG. 2 is a flow chart of the fabrication of a filter chip.

The method comprises the following specific implementation steps:

the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiment is only one embodiment of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

1. The preparation steps of the negative oxygen ion protoplasm are shown in figure 1:

BZ 1: preparing materials: preparing the following materials in percentage by weight: 10 parts of high-purity germanite, 5 parts of cerium oxide, 40 parts of high-purity tourmaline, 10 parts of conductive titanium dioxide, 5 parts of volcanic rock, 5 parts of medical stone, 10 parts of neodymium iron boron, 2 parts of rare earth zirconium, 1 part of rare earth lanthanum, 5 parts of cerium oxide, 1 part of rare earth terbium and 1 part of rare earth ytterbium;

BZ2 grinding: respectively placing the rare earth ytterbium and the rare earth terbium in a grinder to grind the particle size of the rare earth terbium to be not more than 300 meshes to obtain 300 meshes of rare earth terbium and rare earth ytterbium powder for later use;

BZ3 preparation of rare earth terbium and rare earth ytterbium particles: making the rare earth ytterbium into particles with the particle size of 0.8-1mmd, and making the rare earth terbium powder into particles with the particle size of 2-3 mmd for later use;

BZ 4: putting 10 parts of neodymium iron boron (N4OSH) into a high-temperature nano grinder, heating to 400 ℃, keeping the temperature for 24 hours, and grinding to 1250 meshes for later use;

BZ 5: 5 parts of rare earth dysprosium is taken and crushed to about 100 meshes for standby;

BZ 6: preparing a mixture: according to the set weight parts, 10 parts of high-purity germanite, 5 parts of cerium oxide, 40 parts of high-purity tourmaline, 5 parts of volcanic rock, 5 parts of medical stone, 2 parts of rare earth zirconium and 1 part of rare earth lanthanum are weighed for standby application of BZ1, crushed to about 100 meshes and put into a stirrer to be stirred for 15-30 minutes at 600r/min to obtain a uniform mixture for standby application;

calcining the BZ7 mixture: calcining the mixture for later use of BZ6 in a vacuum heating furnace, heating to 2950-3000 ℃, keeping the temperature constant for 120 hours, cooling to 2550 ℃, injecting BZ5 rare earth dysprosium particles for later use, keeping the temperature constant for 24 hours, cooling to 1350 ℃, injecting BZ3 by weight of rare earth terbium particles for later use, keeping the temperature constant for 24 hours, cooling to 800 ℃, injecting 1 part by weight of BZ3 by weight of rare earth ytterbium particles and 10 parts by weight of conductive titanium dioxide, keeping the temperature constant for 12 hours, cooling to 420 ℃, injecting 10 parts by weight of BZ4 by weight of neodymium iron boron powder for later use, continuously cooling to 20 ℃, injecting 40 parts by weight of purified water, opening a furnace cover after half an hour, and filtering by using a 50-mesh steel net to obtain the crude negative oxygen ion stock.

BZ8 grinding: and (3) grinding the coarse material obtained from the BZ7 in a grinder to 1250 meshes to obtain the high-concentration negative oxygen ion raw stock.

BZ9 recovering rare earth ytterbium and terbium: recovering rare earth ytterbium and rare earth terbium from the residue of BZ 7.

2. The steps of manufacturing the filter chip based on the negative oxygen ion raw stock are shown in fig. 2:

s1: preparing a fabric: cutting the high-grade pure cotton fabric into pieces with the width of 1 meter for later use;

cutting the N95 melt-blown fabric according to the size of (125mm multiplied by 85mm) and processing the selvedges; cutting high-grade non-woven fabric according to the size of (125mm multiplied by 85mm) and processing the edge;

s2: implanting negative oxygen ions: heating the primary negative oxygen ion pulp to 40 ℃, adding the pure cotton cloth fabric prepared in S1, heating to 60 ℃, keeping the temperature for 20 hours, and cooling to normal temperature;

s3: making ofNegative oxygen ion protoplasm cloth: taking out the fabric from S2, drying by pressing to remove water, and obtaining the negative oxygen ion release amount of 1500-³"negative oxygen ion protoplasm cloth;

s4: manufacturing an inner core: pressing the non-woven fabric prepared in the step S1 outside the two layers of melt-blown fabric by a hot pressing method to form a four-layer inner core;

s5: manufacturing a filter chip: sewing the negative oxygen ion raw pulp cloth of S3 on the outer surface of the four-layer inner core of S4 to wrap the outer surface of the four-layer inner core, thereby obtaining a negative oxygen ion filter chip;

the filter chip manufactured by the steps can achieve the purposes of resisting bacteria and haze and purifying the breathing air.

3. Manufacturing a chip sleeve:

the pure cotton cloth is cut into small blocks of 130mm x 110mm, the small blocks are sewn inside the mask, and the left end and the right end are not sewn, namely the chip sleeve. When in use, the filter chip is inserted into the chip sleeve, and the filter chip is taken out when the mask is cleaned.

Claims (3)

1. A manufacturing method of a negative oxygen ion mask is characterized in that negative oxygen ion cloth manufactured based on negative oxygen ion raw stock is used as a core material for generating negative oxygen ions, N95 melt-blown cloth and non-woven cloth are arranged in the negative oxygen ion cloth to form six layers of filter chips, and the effects of resisting bacteria, preventing haze, purifying air and the like are achieved.

2. The method for manufacturing a negative oxygen ion mask according to claim 1, wherein the negative oxygen ion raw pulp manufacturing step comprises:

BZ 1: preparing materials: preparing the following materials in percentage by weight: 10 parts of high-purity germanite, 5 parts of cerium oxide, 40 parts of high-purity tourmaline, 10 parts of conductive titanium dioxide, 5 parts of volcanic rock, 5 parts of medical stone, 10 parts of neodymium iron boron, 2 parts of rare earth zirconium, 1 part of rare earth lanthanum, 5 parts of cerium oxide, 1 part of rare earth terbium and 1 part of rare earth ytterbium;

BZ 2: grinding: respectively placing the rare earth ytterbium and the rare earth terbium in a grinder to grind the particle size of the rare earth terbium to be not more than 300 meshes to obtain 300 meshes of rare earth terbium and rare earth ytterbium powder for later use;

BZ 3: preparing rare earth terbium and rare earth ytterbium particles: making the rare earth ytterbium into particles with the particle size of 0.8-1mmd, and making the rare earth terbium powder into particles with the particle size of 2-3 mmd for later use;

BZ 4: putting 10 parts of neodymium iron boron (N40SH) into a high-temperature nano grinder, heating to 400 ℃, keeping the temperature for 24 hours, and grinding to 1250 meshes for later use;

BZ 5: 5 parts of rare earth dysprosium is taken and crushed to about 100 meshes for standby;

BZ 6: preparing a mixture: crushing 10 parts of high-purity germanite, 5 parts of cerium oxide, 40 parts of high-purity tourmaline, 5 parts of volcanic rock, 5 parts of medical stone, 2 parts of rare earth zirconium and 1 part of rare earth lanthanum which are prepared by BZ1 according to the set weight parts to 100 meshes, and stirring the crushed materials in a stirrer at a speed of 100r/min for 15 to 30 minutes to obtain a uniform mixture for later use;

BZ 7: and (3) calcining the mixture: calcining a mixture for later use of BZ6 in a vacuum heating furnace, heating to 2950-3000 ℃, keeping the temperature constant for 120 hours, cooling to 2550 ℃, injecting BZ5 rare earth dysprosium particles for later use, keeping the temperature constant for 24 hours, cooling to 1350 ℃, injecting BZ3 by 1 part by weight of rare earth terbium particles for later use, keeping the temperature constant for 24 hours, then cooling to 800 ℃, injecting BZ3 by 1 part by weight of rare earth ytterbium particles and 10 parts by weight of conductive titanium dioxide, keeping the temperature constant for 12 hours, cooling to 420 ℃, injecting BZ4 by 10 parts by weight of neodymium iron boron powder for later use, continuously cooling to 20 ℃, injecting 40 parts by weight of purified water, opening a furnace cover after half an hour, and filtering by using a 50-mesh steel net to obtain the crude negative oxygen ion stock;

BZ 8: grinding: grinding the coarse material obtained from the BZ7 in a grinder to 1250 meshes to obtain high-concentration negative oxygen ion raw stock;

BZ 9: recovering ytterbium and terbium: recovering rare earth ytterbium and rare earth terbium from the residue of BZ 7.

3. The method comprises the following steps of preparing a negative oxygen ion mask filter chip based on negative oxygen ion raw stock:

s1: preparing a fabric: cutting the high-grade pure cotton fabric into pieces with the width of 1 meter for later use;

cutting the N95 melt-blown fabric according to the size of (125mm multiplied by 85mm) and processing the selvedges; cutting high-grade non-woven fabric according to the size of (125mm multiplied by 85mm) and processing the edge;

s2: implanting negative oxygen ions: heating the primary negative oxygen ion pulp to 40 ℃, adding the pure cotton cloth fabric prepared in S1, heating to 60 ℃, keeping the temperature for 20 hours, and cooling to normal temperature;

s3: manufacturing negative oxygen ion cloth: taking out the fabric from S2, drying by pressing to remove water to obtain negative oxygen ion release amount of 1500/cm³"finished negative oxygen ion cloth;

s4: manufacturing an inner core: pressing the non-woven fabric prepared in the step S1 outside the two layers of melt-blown fabric by a hot pressing method to form a four-layer inner core;

s5: manufacturing a filter chip: and sewing the negative oxygen ion cloth of S3 on the outer surface of the four-layer core of S4 to wrap the negative oxygen ion mask filter chip.

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