KR20030052372A - Bio-Wave Steel Plate Having Antibacteria Property - Google Patents

Abstract

PURPOSE: Resin-coated biowave steel is provided, which radiates a far infrared ray with a radiation ratio of 0.85 or more and exhibits antibacterial power of 90 % or more. CONSTITUTION: The resin-coated steel comprises 100 parts by weight of a resin; and 5-100 parts by weight of at least one kind of far infrared ray radiating powder selected from the group consisting of MgO, Mg(OH)2, ZnO, Zn(OH)2 and CaCO3, wherein the far infrared ray radiating powder is coated with the resin with a dry coating thickness of 5-60 micrometers. Preferably the far infrared ray radiating powder is MgO or Mg(OH)2 and its content is 5-100 parts by weight based on 100 parts by weight of the resin, and shows an antibacterial power of 90 % or more; the far infrared ray radiating powder is ZnO or Zn(OH)2 and its content is 20-100 parts by weight based on 100 parts by weight of the resin, and shows an antibacterial power of 90 % or more; and the far infrared ray radiating powder is CaCO3 and its content is 30-100 parts by weight based on 100 parts by weight of the resin, and shows an antibacterial power of 90 % or more.

Description

Bio-Wave Steel Plate Having Antibacteria Property}

The present invention relates to a biowave steel sheet having antimicrobial properties, and more particularly, to a biowave steel sheet having antimicrobial properties as well as harmful electromagnetic wave shielding properties and far-infrared radiation coated with far-infrared radiation powder having antimicrobial properties.

Recently, as the harmfulness of electromagnetic waves is known, methods and materials for blocking them are emerging. Electromagnetic waves are waves that have electromagnetic field components. Waves that have an adverse effect on the human body are called harmful waves. In particular, in recent years, low-frequency harmonics having magnetic properties have been highlighted. In addition, when the human body is exposed to low frequency electromagnetic waves having magnetic properties for a long time, an induced current is generated in the human body, causing imbalance of various ions such as Na +, K +, and Cl- in the cell membrane, which affects hormone secretion and immune cells. It is known. In addition, research has been reported that the magnetic field is associated with insomnia upon long-term exposure by changing the amount of melatonin secreted related to human sleep. In order to block such harmful electromagnetic waves, the material shielding technology as well as the facility shielding technology should be combined. Currently, copper, aluminum, and the like are mainly used as electromagnetic wave shielding materials, and the present inventors have previously applied for a steel material having excellent magnetic shielding ability at low frequencies (Korean Patent Application No. 1999-52018). However, the steel sheet having excellent low-frequency electromagnetic shielding ability has a disadvantage in that it cannot be used as a far-infrared radiator because the far-infrared radiation is low.

On the other hand, some electromagnetic waves are beneficial to the human body, which is far-infrared. Infrared radiation is a kind of electromagnetic wave that is slightly longer than visible light but has a very high frequency. Far infrared rays are light energy in the range of 2.5 ~ 20㎛ which is a long wavelength among infrared rays, which can be also called waves having electric and magnetic fields. Far-infrared radiation is emitted above the absolute temperature of 0 K in all materials, but in the case of specific ceramics, the radiation is very high, which is called a far-infrared radiator. Far infrared rays have high energy efficiency because energy is transmitted by radiation, and thus, they are widely applied. In addition, recently, as the efficacy on the human body is known, it is being used for various purposes from far-infrared saunas to home appliances, building materials, and general household goods.

However, such far-infrared emitters have almost no conductivity and permeability and thus cannot be expected to shield electromagnetic waves.

On the other hand, in order to improve the far-infrared radiation activity of the steel sheet, a technique of applying heat-infrared ceramic to the steel sheet to improve heat resistance (Japanese Patent Publication No. 95-248231) and a technique of coating the far-infrared radiation element on the copper plate (Korean Patent No. 93-23639) And the technique of corroding stainless steel plate to make far-infrared radiator (Korean Patent No. 90-22365), but it has the disadvantage that it is not possible to expect low-frequency electromagnetic field shielding and high-efficiency far-infrared radiation at the same time. Has previously applied a technology related to a bio-wave steel sheet coated with a coating material having electromagnetic shielding ability and radiating far infrared rays on its surface layer.

Furthermore, in recent years, as a multi-functional bio products are required, antimicrobial properties are also required in building materials and home appliance panels. Therefore, the marketability of the steel sheet having a high antimicrobial activity in addition to the electromagnetic shielding and far-infrared radiation activity is increasing.

In general, a method of imparting antimicrobial properties to a steel sheet includes a method of containing copper and niobium having antimicrobial properties on a stainless steel sheet (Korean Patent 1999-84513) and a phosphate-based coating layer when manufacturing a resin coated steel sheet such as PCM (Pre Coated Metal). A material containing silver (Ag) -carried antimicrobial agent was administered (Korean Patent 1996-058162) and a zeolite carrier having far-infrared radiation contained inorganic antibacterial agents such as Zn and Ag (Korean Patent 1998-83239). have. However, the carrier containing the antimicrobial metal ions is very expensive and its application is limited.

An object of the present invention is to provide a resin coated steel sheet having antimicrobial and far-infrared radiation activity using the antimicrobial activity of the powder itself without requiring any treatment.

Another object of the present invention is to provide a bio wave steel plate having excellent antimicrobial and far infrared radiation as well as harmful electromagnetic shielding ability.

According to the invention,

Resin containing 5-100 parts by weight of at least one kind of far-infrared radiation ceramic powder selected from the group consisting of MgO, Mg (OH) ₂ , ZnO, Zn (OH) ₂ and CaCO ₃ per 100 parts by weight of resin There is provided a resin coated steel sheet having antimicrobial and far infrared radiation coated with a dry coating thickness.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail.

We have found that certain alkaline oxides have antimicrobial as well as good far-infrared radiation. That is, the alkaline oxide reacts upon contact with water to form metal hydroxides such as M (OH) or M (OH) ₂ (M is an alkaline metal ion). Such hydroxides are weakly alkaline and exhibit strong antimicrobial activity as well as far-infrared radiation.

However, Na ₂ O, K ₂ O and CaO among alkaline oxides are so far soluble in water that they dissolve in alkali such as NaOH, KOH, Ca (OH) ₂ together with strong heat generation when contacted with water, so they can be used as far-infrared powder. Can't. In addition, a solution in which Na ₂ O, K ₂ O and CaO in alkaline oxides are dissolved in contact with water becomes a strong base of pH = 11 or more, so the powder itself is antimicrobial but harmful to the human body.

In contrast, alkaline oxide powders such as MgO and ZnO, when exposed to air, react only with a small amount of water on the surface of the powder by direct contact with water or water in the air to form hydroxides. Thus, the pH of the powder surface is 7.5-10.5. It is changed to a degree of weak alkali.

The chemical reaction with water at the surface of the powder is believed to proceed as follows.

MgO, ZnO + 2 H₂O ---> Mg (OH)₂, Zn (OH)₂

In general, bacteria are very vulnerable to changes in the surrounding environment, the bacteria are effectively suppressed when the environment changes to weak alkali of pH 7.5 ~ 10.5. In particular, weakly alkaline oxides and hydroxides having a pH of 7.5 to 10.5 are harmless to the human body so that they can be used as hot spring water, alkaline foods and antacids.

Therefore, MgO and ZnO metal oxides having excellent far-infrared radiation characteristics and having a pH of 7.5 to 10.5 can be used as bio-ceramic powders having antibacterial properties.

On the other hand, the present inventors also found that the far infrared radiation of CaCO ₃ is excellent and, in particular, the antibacterial function is excellent in the study on the antibacterial property of the white far infrared emitter. Unlike the antibacterial action of ZnO and MgO, CaCO ₃ does not change the surrounding pH, but the powder itself is antibacterial. In other words, it is believed that only some of the carbonic acid groups dissolve and act as antibacterial agents. However, the antimicrobial activity of CaCO ₃ is weak compared to ZnO and MgO. Thus, a mixture of CaCO ₃ with a resin in order to impart antimicrobial properties to a steel sheet when painting process to the steel sheet are to be mixed in a greater amount than the CaCO ₃ to ZnO, Zn (OH) _2, MgO and Mg (OH) ₂ do.

Thus, the alkaline far-infrared radiation powder having antimicrobial and far-infrared radiation applicable to the present invention is selected from the group consisting of MgO, Mg (OH) ₂ , ZnO, Zn (OH) ₂ and CaCO ₃ .

The powder having far-infrared radioactive and antimicrobial properties (hereinafter referred to simply as 'radiant powder') is mixed with a resin to be applied to the steel sheet and applied to the steel sheet together with the resin. The resin may be any resin generally used for coating steel sheets, and examples of the resin include, but are not limited to, any general resins commercially used for resin coating of steel sheets such as polyester resins and acrylic resins. .

The spinning powder may be mixed in the resin at 5 to 100 parts by weight per 100 parts by weight of the resin.

If the content of the radiation powder is less than 5 parts by weight, the antimicrobial and far-infrared radiation activity is insufficient. On the other hand, as the content of the radiation powder in the resin increases the far-infrared radiation increases, so considering only the far-infrared radiation, the greater the content of the radiation powder. However, when the resin content is added in excess of 100 parts by weight, coating film adhesiveness and miscibility with other pigments are lowered.

However, the amount of spinning powder required to exhibit critical antimicrobial properties depends on the type of spinning powder. For example, in order for the resin coated steel sheet to exhibit an antibacterial rate of 90% or more, the minimum content of the spinning powder to be contained in the resin coating layer depends on the type of spinning powder. That is, the content of the spinning powder relative to 100 parts by weight of the resin for the anti-microbial activity of the coated steel sheet is at least 5 parts by weight of MgO or Mg (OH) _2, at least 20 parts by weight of ZnO or Zn (OH) ₂ and CaCO ₃ is 30 weight part or more.

Furthermore, a hardening agent, a matting agent, a dispersing agent, etc. which are generally added to the resin composition for coating a steel sheet may be added to the resin to which the spinning powder is added as necessary.

When the resin mixed with the far infrared radiation powder is coated, the far infrared radiation of the steel sheet increases according to the coating thickness. When the resin mixed with the spinning powder is coated on a steel sheet with a dry coating thickness of at least 5 μm, the antimicrobial power of 90% or more and far infrared emissivity of 0.85 or more are shown. When coated with a dry coating thickness of 15 μm, far-infrared emissivity of 0.90 or more is shown.

Even if the dry coating thickness exceeds 60 μm, the far-infrared radiation efficiency does not increase any more, so that the increase in the thickness of the coating is meaningless, but the adhesion of the coating may be deteriorated. However, in particular, it is preferable to coat with a dry film thickness of less than 30 ㎛ which is PCM coating condition in PCM (Pre Coated Metal) coating, and in case of general resin coating which is not continuous coating, it can be thick coated with 60 ㎛ dry thickness. . Therefore, the resin in which the spinning powder is mixed is preferably coated with a dry coating thickness of 5-60 µm, preferably 5-30 µm, on the steel sheet.

Biowave steel sheet of the present invention can be used for the control and removal of any fungi, but exhibits excellent antimicrobial activity, especially against E. coli and Pseudomonas aeruginosa.

The radiation powder of the present invention is not particularly limited to the steel sheet to which the resin is applicable, and may be applied to any steel sheet to impart far-infrared radiation and antimicrobial properties.

Furthermore, by applying the resin mixed with the radiation powder to a steel sheet having an electromagnetic shielding ability, it can be provided as a biowave steel sheet having not only antibacterial and far-infrared radiation activity, but also electromagnetic shielding ability. The steel sheet having electromagnetic shielding properties is not limited thereto, but examples include steel sheets having a maximum magnetic permeability of 2,000 or more at a frequency of 60 Hz according to Korean Patent Application 2000-81056. Bio-Wave Steel Plate refers to a steel plate that blocks harmful electromagnetic waves and emits far-infrared rays .

Hereinafter, the present invention will be described in detail through examples. However, the following Examples do not limit the present invention.

(Example 1)

The far-infrared radiation powder of the following Table 1 was mixed with the polyester resin in the quantity of the following Table 1, respectively, and the coating material was prepared.

Subsequently, the coating material was coated on a steel sheet having excellent electromagnetic shielding properties with a maximum permeability of 3000 at a frequency of low frequency of 3000 at a low frequency using a bar coater to be dried, as shown in Table 1 below. After coating, baking was baked at 225 ° C. to prepare a polyester-based coated steel sheet. Then, the far-infrared radiation characteristic of each polyester-coated steel sheet was measured in the wavelength range of 5-20 micrometers, and it is shown in Table 1.

In addition, the antimicrobial activity of the steel sheet was evaluated by the Korea Institute of Building Materials and Materials (KICM-FIR-1002) by pressure bonding method. The evaluation method was inoculated with E. coli (ATCC 25922) and Pseudomonas aeruginosa (ATCC 15422) in a sample containing a standard sample (sample without antibacterial ceramic) and antimicrobial radiation powder to measure antimicrobial activity, and then inoculated with another sample and covered with the inoculated sample 37 After incubation for 24 hours at ℃, the killing rate of the bacteria was measured as the bacterial reduction rate is shown in Table 1.

division Type of spinning powder in resin Content of spinning powder per 100 parts by weight of PE resin (parts by weight) Coating thickness (㎛) Far infrared radiation rate E. coli reduction rate (%) Pseudomonas aeruginosa reduction rate (%) Comparative material 1 none 0 20 0.834 0 0 Invention 1 MgO 30 5 0.867 99.3 93.4 Invention Material 2 MgO 30 10 0.895 99.9 99.3 Invention 3 MgO 5 20 0.868 98.5 93.6 Invention 4 MgO 10 20 0.890 98.9 94.9 Invention 5 MgO 20 20 0.923 99.3 93.7 Invention Material 6 MgO 30 20 0.924 99.3 99.3 Comparative material 2 ZnO 15 20 0.904 29.7 88.7 Invention Material 7 ZnO 25 20 0.910 99.7 93.6 Invention Material 8 ZnO 35 20 0.912 99.6 93.8 Comparative material 3 CaCO ₃ 10 20 0.897 24.5 20.0 Comparative material 4 CaCO ₃ 20 20 0.916 96.7 80.6 Invention Material 9 CaCO ₃ 30 20 0.925 98.7 99.3

As can be seen in Table 1, the steel sheet treated with Comparative Material 1, which does not contain the spinning powder, has a very low far-infrared emissivity and shows no antibacterial activity.

As in Inventive Materials 1 and 2, the far-infrared radiation dose increased as the thickness of the coating film increased, but the antibacterial property was almost independent of the thickness. That is, even when coated with a thickness of 5-10㎛ showed excellent antibacterial activity of more than 90%. Further, in the case of the invention materials 1 and 2, the far-infrared emissivity is somewhat low, but 90% of the antimicrobial properties are secured, and in particular, in addition to PCM coating, for example, various resins such as anti-fingerprint coating and 5-10 탆 coating coating It can also be used as a painting method. However, more than 0.8 5 Emissivity, which is the minimum condition of the far-infrared radiator of the invention, even if material 1 and 2 is shown.

MgO showed an antimicrobial activity of 90% or more even if only 5-10 parts by weight of 100 parts by weight of the resin was added. In other words, the steel sheet of Inventive Materials 3 and 4 had a far lower infrared radiation characteristic of 0.85-0.90, but showed excellent antibacterial characteristics. However, in order to obtain far-infrared emissivity of 0.90 or more, it is preferable to add 10 parts by weight or more of MgO powder per 100 parts by weight of resin as in Inventive Materials 5 and 6.

When the content of ZnO is 20 parts by weight or more per 100 parts by weight of the resin (Inventive material 7, 8) and CaCO ₃ is more than 30% by weight per 100 parts by weight of the resin (Inventive material 9). Indicated.

Resin-coated steel sheet containing far-infrared radiation powder exhibits excellent antimicrobial activity of 90% or more and far-infrared emissivity of 0.85 or more. Furthermore, when a resin containing far-infrared radiation powder is coated on a steel plate having electromagnetic wave shielding ability, it has electromagnetic shielding ability as well as antimicrobial activity and far-infrared radiation activity.

Claims (8)

Resin containing 5-100 parts by weight per 100 parts by weight of at least one kind of far-infrared radiation powder selected from the group consisting of MgO, Mg (OH) ₂ , ZnO, Zn (OH) ₂ and CaCO ₃ Resin coated steel sheet having antimicrobial and far infrared radiation coated with a coating thickness. The resin coated steel sheet according to claim 1, wherein the dry coating thickness is 5-30 탆. The resin coated steel sheet according to claim 1, wherein the resin coated steel sheet has a far-infrared emissivity of 0.85 or more and an antibacterial activity of 90% or more. The resin coated steel sheet according to claim 2, wherein the far-infrared emissivity is 0.90 or more. The method of any one of claims 1 to 4, wherein the far-infrared radiation ceramic powder is MgO or Mg (OH) ₂ and MgO or Mg (OH) ₂ powder is contained in 5-100phr per 100 parts by weight of the resin, the antimicrobial activity of more than 90% Resin coated steel sheet characterized by having. The method according to any one of claims 1 to 4, wherein the far-infrared radiation ceramic powder is ZnO or Zn (OH) ₂ and ZnO or Zn (OH) ₂ powder is contained in the resin at 20-100 parts by weight per 100 parts by weight of the resin, 90% Resin coated steel sheet characterized by having the above antibacterial activity. The resin coating according to any one of claims 1 to 4, wherein the far-infrared radiation ceramic powder is CaCO ₃ and the CaCO ₃ powder is contained in the resin at 30-100 parts by weight per 100 parts by weight of the resin, and has an antibacterial activity of 90% or more. Grater. 5. The resin-coated steel sheet according to any one of claims 1 to 4, wherein the steel sheet is an electromagnetic shielding steel sheet having a maximum permeability of 2000 or more by a time-varying magnetic field at 60 Hz.