KR100944384B1 - Far-infrared rays device for drying painting - Google Patents

Abstract

The present invention is a far-infrared coating drying apparatus including a substrate, a heating layer and a radiant heat radiating layer in a stacked form, wherein the radiant heat radiating layer is TiO ₂ , SiO ₂ , ZrO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , MnO ₂ A far-infrared paint drying apparatus characterized by applying a mixture of a radiant inorganic substance, an alkoxy silane adhesive and an alcohol solvent, and then drying the solvent to form a radiant heat radiating layer.

Far Infrared, Infrared, Automotive, Paint, Painting, Drying, Radiation, Radiant Heat

Description

Far-infrared rays device for drying painting

The present invention relates to a far-infrared paint drying apparatus for paint drying of automobiles and the like. Specifically, the present invention relates to a far-infrared paint drying apparatus that can be used as an efficient drying apparatus by radiating high-frequency radiant heat electromagnetic waves with a high penetration force to a dry matter with high efficiency.

The emphasis on regulatory and energy savings around the world, such as climate change agreements, GHG emission regulations, and rising oil prices, has led to national energy issues. As the use of national energy facilities increases rapidly with industrial development, efforts to develop high-efficiency energy-saving devices and field applications are very necessary.

In Korea, coal, coal, etc. have been mainly used since the 19th century as energy materials, and recently, oil and gas have been used a lot. However, these fossil energy has a problem of global warming due to the carbon dioxide generated in use, there is a problem of finite resources. Therefore, the development of non-fossil energy, such as nuclear power and alternative energy, is being actively made. However, nuclear power needs time to converge on public opinion because of the harmfulness of radiation. In addition, alternative energy development is still in its infancy, and there is a problem that expensive development costs are required.

Therefore, not only the development of alternative energy but also the development of high-efficiency electric devices with low energy consumption is a very important national task.

Drying is a unit operation that removes moisture by using heat, air flow, electromagnetic waves, etc. to a dry object, and a dryer is a device that removes moisture by using a large amount of energy. The dryer can be divided into convection, conduction and radiation based on the heat source transfer method. Convection type is a method of heating the air indirectly through the medium by heating the air to generate a hot air, etc., such as box type, band type, tunnel type ventilation drum type, fluidized bed type, vibrating type, spray type, rotary type, and the like. The conduction type is a method of transferring heat directly to a dry object by conduction phenomenon, and there are disc type, paddle type, stirring type, and the like. Radiation is a method of directly transferring heat by applying energy directly to an object without an intermediate medium, which uses infrared, high frequency, microwave, and microwave. Conventional radiant dryers do not provide satisfactory heat transfer by radiant heat alone, and thus, a combined dryer is mainly used by mixing with hot air drying, which is a convection method.

On the other hand, looking at the conventional car paint dryer has the following problems.

First, there is a problem that the energy loss is not small due to low thermal efficiency. In the case of a convection hot air dryer, heat is inevitably generated during the heat transfer process by heating the air once and then transferring the heat to the dried material, and in the case of the near-infrared dryer of the present invention, the far infrared dryer of the present invention Since the heat source was rather high temperature, not only radiation but also heat release due to convection or conduction phenomena, which led to unnecessary heat loss.

Second, the rate of product defects such as bubbling, blushing, bleeding, lifting, lake of drying, and pin-holes during car drying is rather high. There is a high problem. Bubbles are dried when bubbles are generated on the surface of the product.They are high when the viscosity of the paint is high and the heating element is wet with moisture.The whitening is white like fog in the coating film. Occurs when the drawing cools and absorbs and condenses water. Smearing is a phenomenon caused by undried paint spewing onto the surface when the paint is overlaid on the less dried paint, and injury occurs when the inside of the product is wrinkled. It is a phenomenon that drying does not itself occur mainly when the coating film is thickly coated. Needle hole is a phenomenon in which a small hole like a needle is formed in the coating film and is caused by the rapid heating of the thick coating film. These phenomena are all caused by differences in thermal conductivity inside or outside the building or by rapid temperature changes. Conventional convection hot air dryers or radiative near-infrared dryers rapidly increase the temperature of the exterior of the building, resulting in a large temperature gradient inside and outside of the building, resulting in somewhat higher defect rates. .

Third, in the conventional dryer, partial and local heating was not possible by heating the whole room or using hot air when drying the automobile paint. In this case, it is not possible to intensively dry the desired part, and there is less dried part, or other parts are over-dried for drying the less dried part. In addition, even if only local drying is necessary, the energy efficiency was not good because the drying process was performed as a whole.

Fourth, the conventional dryer has a safety problem such as a burn hazard. Conventional dryers are exposed to high temperature hot air or high temperature heat sources, which creates a risk of burns to workers during drying operations. Therefore, very careful attention of the workers was required for the operation of the dryer during the drying operation, and carelessness could lead to industrial accidents and cause human and economic losses.

In order to solve the above problems, it is an object of the present invention to provide a high efficiency far-infrared paint drying apparatus. Unlike conventional hot air dryers, which are convection type, heat is directly transmitted to a dry object without a heat transfer medium, and thus, thermal efficiency is high, and a drying rate per unit energy is excellent because a low temperature heat source is used and a far infrared emissivity is higher than that of a conventional near infrared dryer.

It is another object of the present invention to provide bubbling, blushing, bleeding, lifting, lake of drying, pin-holes that conventional dryers have caused during drying of automobiles. It is to provide a far-infrared paint drying device that reduces the rate of product defects, such as). Unlike conventional convection hot air dryers, since radiation uses strong penetrating power, heat is simultaneously transferred to the outside and the inside, and thus the occurrence rate of the defect due to the sudden temperature difference between the outside and the inside is significantly low. In addition, unlike near-infrared dryers, the use of a far-infrared ray with a low temperature of the heat source significantly lowers the defect occurrence rate due to a sudden temperature change on the surface.

Another object of the present invention is to provide a far-infrared paint drying apparatus capable of partial and local heating. Unlike the conventional dryer, the far-infrared paint drying apparatus of the present invention can be made in the form of a panel, and in this case, local drying is possible by operating only a part of the panel that needs to be dried. Therefore, unlike the conventional dryer, the problem of partial undrying and overdrying can be solved, and energy used for drying unnecessary parts can be reduced.

Still another object of the present invention is to provide a far-infrared paint drying apparatus in which a conventional dryer does not have safety problems such as a burn hazard. Far infrared coating drying apparatus of the present invention is very safe compared to the conventional drying apparatus because the temperature of the radiant heat radiating layer is only about 170 ℃ average. Therefore, the present invention has the effect of reducing industrial accidents.

As the background art, those of Documents 1 to 3 may be mentioned. The present invention relates to a paint drying apparatus using far infrared rays, and more particularly, to a far infrared paint drying apparatus having far better emissivity than a conventional far infrared drying apparatus.

The emissivity (ε) value refers to the rate at which an object absorbs, transmits, and reflects external infrared energy. In theory, an object that only absorbs external energy and does not reflect it is referred to as "blackbody", and the emissivity (ε) value is " Defined as 1 ". However, in general objects, the amount of energy absorbed and reflected varies depending on the surface conditions such as gloss, roughness, and oxidation. That is, when the ratio of absorbed and reflected energy is based on "Blackbody", it actually has a value smaller than "1", and the closer the emissivity is to 1, the higher the energy efficiency of the far infrared device.

The present invention relates to a far-infrared paint drying apparatus that has an innovatively increased emissivity by optimally selecting a content ratio of a radiant heat-radiating layer material having a very high level of far-infrared emissivity and increasing the surface roughness through the surface roughening coating layer. While the emissivity of the conventional far-infrared device is about 87-91%, the emissivity of the far-infrared paint drying device of the present invention is 94.8% and has a very high level of far-infrared emissivity.

[Reference 1] KR 10-1990-0002709 A 1990. 2. 28.

[Document 2] KR 10-2001-0041738 A 2001 11. 7.

Document 3 KR 10-2004-0028856 A 2004. 4. 27.

SUMMARY To achieve the above object of the present invention, a substrate, a heating layer and a radiant heat-emitting layer includes a stacked form, and the radiant heat-emitting layer is a TiO ₂ 6-12 wt%, SiO ₂ 20-30 wt%, ZrO ₂ 5-10% by weight, 5-10% by weight of Al ₂ O _3, 5-10% by weight of Fe ₂ O _3, 5-10% by weight of MnO ₂ , Na ₂ 0 1-5% by weight, with an alkoxy silane It provides a far-infrared paint drying apparatus, characterized in that formed by applying a mixture of 20-25% by weight of the adhesive and 10-15% by weight of the alcohol solvent, followed by drying the solvent.

In the far-infrared paint drying apparatus, there is provided a far-infrared paint drying apparatus further comprising a surface uneven coating layer on the radiant heat radiating surface of the radiant heat radiating layer.

In the far-infrared paint drying apparatus, the surface roughness coating layer is SiO ₂ And it provides a far-infrared coating drying apparatus, characterized in that formed by coating and then drying the supersaturated aqueous solution mixed with a CaO ₂ weight ratio of 1: 4 on the surface of the radiant heat radiating layer.

In the far-infrared paint drying apparatus, the substrate provides a far-infrared paint drying apparatus, characterized in that the aluminum plate or stainless steel plate.

Far-infrared paint drying apparatus according to the present invention is a heat transfer in the form of radiation rather than a heat transfer method through the medium is a fast drying speed for the dry object, the thermal efficiency is good because it does not go through a heat transfer medium has a large energy saving effect. In particular, the far-infrared paint drying apparatus of the present invention emits 2.5-25 μm radiant heat at a high emissivity of 94.8%, thereby greatly saving energy.

The present invention is a far-infrared coating drying apparatus including a substrate, a heating layer and a radiant heat radiating layer in a stacked form, wherein the radiant heat radiating layer comprises 6-12 wt% TiO ₂ , 20-30 wt% SiO ₂ , and ZrO ₂ 5-10. 5% by weight of Al ₂ O _3, 5-10% by weight of Fe ₂ O _3, 5-10% by weight of MnO ₂ , ₁ 2-5% by weight of Na ₂ 0 with an alkoxy silane adhesive 20- After applying a mixture of 25% by weight and 10-15% by weight of the alcohol solvent, there is provided a far-infrared paint drying apparatus, characterized in that formed by drying the solvent.

The far-infrared coating drying apparatus according to the present invention may be stacked in the order of the substrate, the heating layer and the radiant heat radiating layer, or may be stacked in the order of the heating layer, the substrate and the radiant heat radiating layer.

Far-infrared coating drying apparatus according to the present invention may be further provided with a heat insulating layer on the outermost surface of the opposite side to the surface provided with the radiant heat radiating layer, and may further be provided with a surface uneven coating layer on the radiating surface of the radiant heat radiating layer. have.

Hereinafter, the present invention will be described in detail.

According to an exemplary embodiment of the present invention, the far-infrared paint drying apparatus of the present invention includes a substrate, a heat generating layer, and a radiant heat radiating layer in a stacked form, and supplies power of 850-2000w / m ² to the heat generating layer. When applied, the radiant heat emissive layer maintains a temperature of 92-250 ° C.

Here, the fact that the radiant heat radiating layer maintains the temperature of 92-250 ° C. when the energy density of 850-2000w / m ² is applied to the heat generating layer means that the radiant heat is supplied by supplying the energy density of 850-2000w / m ^{2 to} the heating layer. When heating the radiating layer, the temperature of the radiant heat radiating layer is initially raised, but after a certain time elapses, the temperature is no longer increased due to energy loss due to radiation of radiant heat or the like, and the temperature of 92-250 ° C. is maintained. it means. Here, the temperature of the radiant heat radiating layer is based on the case where the ambient temperature is 20-40 degreeC, and is as follows.

Radiation is the phenomenon in which particle beams or electromagnetic waves are emitted by natural and artificial phenomena and actions other than atomic nucleus and small particle conversion. Most substances, regardless of whether they are organic or inorganic, have a high temperature when heat is applied, and the amount or wavelength of radiation emitted is different, but radiates a predetermined amount of radiant heat. However, in the present invention, the radiant heat radiating layer maintains a temperature of 92-250 ° C. and radiates radiant heat when an energy density of 850-2000 w / m ² is applied to the heating layer. The inventors of the present invention show that the radiant heat radiating layer comprises 6-12% by weight of TiO ₂ , 20-30% by weight of SiO ₂ , 5-10% by weight of ZrO _2, 5-10% by weight of Al ₂ O _3, 5-10% by weight of Fe ₂ O _3. After applying a mixture of 5-10% by weight of the MnO ₂ radiation inorganic material, 20-25% by weight of the alkoxy silane adhesive and 10-15% by weight of the alcohol solvent, the solvent was dried to form and the temperature of the radiant heat-emitting layer It has been found that the radiant heat radiation efficiency is high at 92-250 ° C. In particular, it has been found that the wavelength of the radiant heat electromagnetic waves can emit radiant heat electromagnetic waves of 2.5 to 25 µm (central wavelength 9 µm).

Radiation heat electromagnetic waves having a wavelength of 2.5 to 25 µm (central wavelength 9 µm) are known to have a very strong penetration force.

In order to maintain the temperature of the radiant heat radiating layer in the present invention at a temperature of 92-250 ° C., the components of the radiant heat radiating layer, the energy density of the power supplied to the device of the present invention, or the configuration of the layers constituting the device of the present invention, etc. The requirements of

In the present invention, in order to form a radiant heat radiating layer, when the energy density of 850-2000w / m ² is applied to the heating layer can be used a material that can be heated by the heating layer to maintain a temperature of 92-250 ℃ . For example, inorganic materials such as TiO ₂ , SiO ₂ , ZrO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , MnO ₂ , 2MgO · 2Al ₂ O ₃ · 5SiO ₂ , Al ₂ O ₃ · TiO _2, and the like may be used. More preferably, an inorganic material selected from the group consisting of TiO ₂ , SiO ₂ , ZrO ₂ , Al ₂ O ₃ , Fe ₂ O _3, and MnO _{2 ,} Na ₂ 0 is used. The inorganic materials may be used alone or in combination. In particular, TiO ₂ is very suitable for maintaining a temperature of 92-250 ° C. when the above-described energy density power is applied to the heat generating layer and heated by the heat generating layer. In addition, when using two or more kinds of inorganic materials selected from the group consisting of TiO ₂ , SiO ₂ , ZrO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , MnO _{2 ,} Na ₂ 0, 2.5 to 25 μm ( It is possible to radiate radiant heat having a central wavelength of 9 µm).

In one embodiment of the invention, a mixture of TiO ₂ , SiO ₂ , ZrO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , MnO _{2 ,} Na ₂ 0 may be used as the radiant heat radiating layer material, in which case The amount used is 6-12 wt% TiO ₂ , 20-30 wt% SiO ₂ , 5-10 wt% ZrO _2, 5-10 wt% Al ₂ O _3, 5-10 wt% Fe ₂ O ₃ , MnO ₂ 5- It is preferred that it is 10% by weight, Na ₂ 0 1-5% by weight, and the remaining amount may be an auxiliary alcohol and / or alkoxy silane. Preferably, the alcohol is used at 10-15% by weight, and the alkoxy silane is preferably used at 20-25% by weight.

The radiant heat radiating layer material used in the present invention is of high purity, preferably of large particle size, for example, of 350 mesh or more.

In the present invention, the radiant heat radiating layer may be formed by mixing the inorganic material as described above with an adhesive and, if necessary, a solvent, applying it to the first surface of the substrate or the heating layer, and then drying. In the present invention, the adhesive for forming the radiant heat radiating layer preferably has thermal conductivity and heat resistance, preferably at least 250 ° C, more preferably at least 300 ° C, and is not particularly limited to the material. . For example, resin, specifically, acrylic resin, epoxy resin, etc. can be used. Moreover, a ketone solvent can be used as said solvent.

In the present invention, the substrate serves to support the radiant heat radiating layer and the heat generating layer, and the material is not particularly limited. The substrate may be composed of a synthetic resin plate, it may be composed of a plate made of stainless steel or aluminum (stainless plate is widely known to those skilled in the art, also known as SUS plate). In the present invention, however, the substrate is excellent in heat resistance, and preferably, there is no chemical and physical change at 92-250 ° C, which is the operating temperature of the apparatus of the present invention, and the thermal expansion coefficient between the operating temperature and 92-250 ° C is in contact with the substrate. It is preferable to have similar peripheral layers, such as a heating layer and a radiant heat radiating layer. In addition, the substrate material is preferably a material which is excellent in thermal conductivity and small in specific gravity, which is helpful in manufacturing the device of the present invention at a light weight. It is important that the device of the present invention be lightweight, either by placing it on a ceiling or wall or by attaching it to a support. In particular, when the far-infrared paint drying apparatus of the present invention has a structure in which a heat generating layer, a substrate, and a radiant heat radiating layer are sequentially stacked, the substrate is preferably composed of an aluminum plate.

In the present invention, the material constituting the heat generating layer is not limited as long as the material can generate heat when power is supplied from the outside. However, it is preferable that the heating layer material has a small change in resistance due to temperature change, that is, a low temperature coefficient of resistance, excellent flexibility, and small physical and chemical changes. For example, when the exothermic thin wire used as the exothermic layer material has low mechanical strength or the surface is oxidized to increase the contact resistance, the operation of the apparatus of the present invention may be adversely affected.

For example, in the present invention, a heating wire such as iron chromium (Fe-Cr), nichrome (Ni-Cr), or copper nickel (Cu-Ni) is preferably a synthetic resin having stability at a high temperature of 300 ° C. or higher, such as polyfluoroethylene-based resin. The resin coated with Teflon, silicone resin, etc. of DuPont made of resin can be used. The heating wire coated with the synthetic resin may generate heat when power is supplied to transfer heat to the radiant heat radiating layer.

In the present invention, the heating layer may be formed by bonding the heating wire coated with the synthetic resin as described above to the substrate using an adhesive. The adhesive which can be used herein is excellent in adhesive strength, heat resistance, preferably at 300 ° C or more, more preferably at 350 ° C or more, and preferably does not deform or crack due to temperature change. In order to quickly transfer the heat generated in the heat generating layer to the radiant heat radiating layer, it is preferable that the thermal conductivity is excellent. In the present invention, various types of adhesives, such as a solution or a gel, can be used.

In the present invention, in the case of adhering the heating wire coated with a synthetic resin to the substrate as described above, in order to ensure adhesion, a foil made of aluminum or the like may be attached to the upper surface to which the heating wire is attached using an adhesive or the like. have.

The far-infrared coating drying apparatus of the present invention may have a structure in which a substrate, a heating layer, and a radiant heat radiating layer are sequentially stacked as illustrated in FIG. 1, but the heating layer, the substrate, and a radiant heat radiating layer are sequentially formed as illustrated in FIG. 2. It may be a stacked structure. However, in the former case, since the heat generating layer must be formed on the substrate, and then the radiant heat radiating layer must be formed thereon, the process may be time consuming and complicated, but in the latter case, The heat generating layer is advantageous in process because it is possible to independently form a radiant heat radiating layer on the other side of the substrate.

The far-infrared paint drying apparatus of the present invention may have a heat insulating layer on the outermost surface of the surface adjacent to the outer surface when the apparatus of the present invention is disposed in a predetermined space, that is, the surface opposite to the surface provided with the radiant heat radiating layer. have. When the heat insulation layer is provided in this way, the heat emitted from the heat generating layer is prevented from radiating to the surface opposite to the surface provided with the radiant heat radiating layer so that radiant heat can be radiated efficiently in the radiant heat radiating layer direction. In addition, it is possible to prevent the fire by blocking the heat generated in the heat generating layer by the heat insulating layer.

In the present invention, the heat insulating layer material is preferably incombustible and lightweight, and for example, it is preferable to use a gypsum board or a high-density glass fiber board, and among these, it is more preferable to use a high-density glass fiber board with light weight and less pollution problem. In the case of using the glass fiber board as the heat insulating layer material, the outer exposed surface of the glass fiber board may be coated with an adhesive treated glass fiber cloth to prevent the exposure of the glass fiber. However, it is not limited to these materials, and any heat insulating material known in the art can be used without limitation. The thickness of the insulating layer may be determined by those skilled in the art in consideration of the weight and volume of the entire apparatus or other processes, but in the present invention, the thickness is most preferably around 25 mm.

The heat insulation layer may be formed by adhering the above-described heat insulation layer material to a substrate or a heat generating layer with an adhesive, or may be formed by assembling with a substrate or a heat generating layer without an adhesive. For example, the device of the present invention can be assembled without adhesive by fixing the heat insulating layer, the heat generating layer, the substrate and the radiant heat radiating layer constituting the device of the present invention with an aluminum frame.

The far-infrared coating drying apparatus of the present invention may further include a surface asperity-coated coating layer on the surface for radiating the radiant heat of the radiant heat radiating layer. Such a coating layer can increase the radiation efficiency by roughening the radiant heat radiating surface of the device of the present invention to increase the radiated area of radiant heat. In addition, when a part of the human body is closed to the surface roughening coating layer, the surface roughening coating layer is a little lower than the radiant heat radiating layer, so there is a side effect that can reduce the risk of burns of the user.

The surface asperity-treated coating layer may be formed of, for example, a mixture of silicon dioxide (SiO ₂ ) and calcium dioxide (CaO ₂ ). As a formation method, a method of adding the above-exemplified materials to water or higher solubility to prepare a supersaturated aqueous solution, coating the surface on the radiant heat radiation layer, and drying the solvent may be used. The degree of supersaturation of the supersaturated aqueous solution is not particularly limited, and it is preferable as long as it can be evenly distributed on the surface of the radiant heat radiation layer. When using such a method, the texture of the particles of the material can be left intact to roughen the surface of the device of the present invention and to increase the radiation surface. That is, when the surface uneven coating layer is formed, irregularities are formed on the smooth surface, and these irregularities increase the outermost surface area, thereby ultimately increasing the emissivity.

The size of the device of the present invention can be determined by one skilled in the art depending on the end use or process conditions. Further, each layer constituting the device of the present invention does not have to be all the same size, and the size can be adjusted as long as it can function as each layer described above.

In the far-infrared coating drying apparatus for radiant heat radiation according to the present invention, the lead wire for supplying the energy density of 850-2000w / m ^{2 to} the heat generating layer is drawn to the outside and connected to a power plug, so that power can be supplied to the apparatus of the present invention. Can be. The far-infrared paint drying apparatus according to the present invention reaches about 92-250 ° C. after about 10 minutes when the rated current starts to flow, when the surface temperature is applied with a desired temperature, that is, 850-2000w / m ² , and the radiant heat electromagnetic radiation is emitted. do. When this radiant heat hits an object, the energy turns into heat, and the temperature of the object begins to rise. As illustrated in FIGS. 3 and 4, when the lead wire for supplying power to the apparatus of the present invention is connected to the power plug via the thermostat, the temperature sensor of the thermostat detects the change of the dried object and detects the contents. The power circuit can be opened and closed accordingly.

The far-infrared paint drying apparatus of the present invention can be mounted on, for example, the front or part surface of the ceiling in a building or a part of the wall surface. In addition, the device of the present invention may be manufactured and applied to a size suitable for the area to be applied, but may be used as a method of using a plurality of devices in the area to be applied to the device of the present invention manufactured to a predetermined size.

In addition, the far-infrared paint drying apparatus may be attached and installed on the ceiling and the wall surface of the drying room and may be used as a paint drying apparatus such as an automobile as shown in FIG. 5. Several drying units attached to the ceiling and walls have separate power supply leads and temperature controllers, allowing for local drying of only the desired area. In other words, if you want to intensively dry the ceiling painting of the car, only the far-infrared paint drying device of the ceiling can be operated locally. In this case, since heat is directly transmitted to the local part of the building by radiant heat, heat transfer to other parts is minimized unlike in the case of hot air drying.

Also, as illustrated in FIG. 6, the far-infrared paint drying apparatus may be used as a small far-infrared paint drying apparatus that is easy to move when attached to the support and the base.

The present invention will be described in more detail with reference to the following Examples. However, the scope of the present invention is not limited by the following examples.

Example

SiO ₂ on the first surface of a pure aluminum substrate having a thickness of 0.6 mm 25 wt%, ZrO ₂ 8 wt%, Al ₂ O ₃ 7 wt%, TiO ₂ 10% by weight (350 mesh powder used), Fe ₂ O ₃ 5 wt% and MnO ₂ A mixture of a radiation inorganic material comprising 5% by weight, Na ₂ 0 3% by weight, a mixture of 25% by weight of an alkoxy silane adhesive and 12% by weight of an alcohol solvent was applied, and then the solvent was dried to form a radiant heat radiating layer. Subsequently, a supersaturated aqueous solution of SiO ₂ and CaO ₂ was coated on the surface of the radiant heat radiating layer, and the solvent was dried to form a surface asperity coated layer. Here, the ratio of SiO ₂ and CaO _{2 in} the supersaturated aqueous solution of SiO ₂ and CaO ₂ may be arbitrarily adjusted, but SiO ₂ : CaO ₂ It is most preferable to set it as 1: 1 (weight ratio) to raise emissivity and to make coating smooth.

Meanwhile, two types of nichrome wire coated with Teflon on the second surface of the aluminum substrate were bonded using an acrylic adhesive to form a heat generating layer. At this time, the nichrome wire was arranged in a zigzag shape so as to be evenly distributed on the entire surface of the heating layer. Subsequently, an aluminum foil was glued onto the nichrome wire coated with the Teflon. Subsequently, a heat insulating layer was formed by placing a glass fiber plate (BOD 96 1000 × 2000) having a thickness of 25 mm on the aluminum foil and fixing it as an aluminum frame.

When a power consumption density of 850-2000 Watt / m ² was supplied to the far-infrared paint drying apparatus manufactured as described above, the temperature of the surface of the surface uneven coating layer was in the range of 92-250 ° C. after 10 minutes, and the glass fiber board The temperature of the heat insulation layer comprised from this was 30-160 degreeC. Radiant heat radiated from the device was measured by the Korea Institute of Energy Research, and the results are shown in FIG.

As shown in FIG. 7, the device exhibited a very high emissivity of 94.8% in the range of 2.49 μm to 25 μm with a temperature of the radiant heat emitting layer of 100 ° C., and the highest emissivity of the 9 μm wavelength band.

Figure 1 shows the structure of a far-infrared paint drying apparatus according to one embodiment of the present invention.

Figure 2 shows the structure of the far-infrared paint drying apparatus according to another embodiment of the present invention.

Figure 3 shows an example of connecting the far-infrared paint drying apparatus according to the present invention to a power plug via a temperature sensor.

Figure 4 shows a schematic diagram of a temperature control system using an artificial intelligence controller for a far-infrared paint drying apparatus according to the present invention.

Figure 5 shows an example in which the far-infrared paint drying apparatus according to the present invention is attached to the ceiling and the wall of the drying room to create a paint drying room for an automobile.

Figure 6 shows an example of a far-infrared paint dryer which is convenient to move by attaching the far-infrared paint drying apparatus according to the present invention to a means having a support and a stand.

7 is a graph showing the emissivity of the far-infrared paint drying apparatus manufactured according to the embodiment.

Claims (4)

A heating layer having a heating wire and generating heat by applying electricity to the heating wire; A radiant heat radiating layer that receives heat generated by the heat generating layer and radiates it as radiant heat; And a substrate provided between the heat generating layer and the radiant heat radiating layer to support these layers and transferring the generated heat of the heat generating layer to the radiant heat radiating layer. The radiant heat radiation layer is 6-12 wt% TiO ₂ , 20-30 wt% SiO ₂ , 5-10 wt% ZrO _2, 5-10 wt% Al ₂ O _3, 5-10 wt% Fe ₂ O ₃ , MnO ₂ 5-10% by weight, Na ₂ 0 1-5% by weight of a radiant inorganic material, a mixture of 20-25% by weight of the alkoxy silane adhesive and 10-15% by weight of the alcohol solvent, followed by drying the solvent , Further provided with a surface concave-convex coating layer on the radiant heat radiating surface of the radiant heat radiating layer, The surface roughening coating layer is a far-infrared paint drying apparatus, characterized in that formed by coating a supersaturated aqueous solution mixed in a weight ratio of SiO ₂ and CaO ₂ = 1: 4 on the surface of the radiant heat radiating layer and dried. The far-infrared coating drying apparatus according to claim 1, wherein when the temperature of the radiant heat radiating layer is 92 to 250 ° C, radiant energy having a wavelength within a range of 2.5 to 25 µm is radiated at an emissivity of 94.0 to 94.8%. delete delete

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