JPH0731135U - Fluid purification device - Google Patents

Abstract

(57) [Summary] (Modified) [Purpose] To purify and activate the air supplied to the combustion base of automobiles, internal combustion engines, etc., and to emit harmful organic substances and inorganic substances, especially nitrogen oxides, in exhaust gas emitted during fuel combustion. The present invention provides a fluid purification device for the purpose of suppressing generation and reducing fuel consumption, and can also be used for purification of water as a fluid. [Constitution] Container 3 provided with a fluid inlet 1 and a fluid outlet 2
A far-infrared radiation layer 5 made of a far-infrared radiation material is contained therein, and a fluid element 8 formed in the form of coating, dipping or attachment is housed therein, and the fluid passing through the fluid element is purified and activated. And

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention purifies and activates the air supplied to the combustion base of an automobile, an internal combustion engine, etc., and suppresses the generation of nitrogen oxides and the reduction of fuel consumption, especially harmful organic substances and inorganic substances in exhaust gas emitted during the combustion of fuel. The present invention provides a fluid purification device for the purpose of the above, and can also be used for purification of water quality as a fluid.

[0002]

2. Description of the Related Art Conventionally, an air purifier for purifying air supplied to a combustion base of an engine of an automobile or the like is generally made of a paper sheet having excellent air permeability, a hard sheet such as a fiber or a synthetic resin cloth is hollow. The air element molded in the wavy ring is housed in a flat hollow ring container having an air intake port and an air exhaust port, and the forced air blows the air to the air element, and the air passing through the air element is It is filtered and delivered to the combustion base via a carburetor or injection. Furthermore, it is only to purify and purify the contaminants in the air, and has no chemical reaction function. In addition to the above-mentioned filtering means, water and oils that are fluids are used, and activated carbon, ceramics, etc. are used as the filtering material.

[0003]

[Problems to be solved by the device]

 An object of the present invention is to provide energy for instantly activating fluids with a simple fluid purification device to promote amplification of functions or various goals originally required of the fluids themselves.

[0004]

[Means for Solving the Problems]

 The means is to store a fluid element having a far-infrared radiation layer in a container provided with a fluid intake port and a fluid outlet port, and the fluid passing through the fluid element is purified and activated, and is in the air as a fluid. Solves the above problems by providing a fluid purification device that purifies this to improve fuel economy of fuel, reduce generation of harmful organic substances, and improve purification of water quality for fluids such as water. I will try.

[0005]

[Action]

 By passing various fluids through the device of the present invention, the fluid is purified by the filter layer in the device, and the characteristic action of the amplified radiation of far-infrared wave excites and vibrates the compositional particles / atoms of the fluid. By breaking the mutual bonds of the constituent molecules and making them ultrafine particles, it is possible to obtain an activated fluid that is rich in reactivity. The far-infrared radiation promptly purifies and activates the fluid, although there are still unidentified effective effects.

[0006]

【Example】

 Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a partially fragmented plan view of an air element in an air purification apparatus for an automobile in an embodiment, and FIG. 2 is a side view thereof. The annular container 3 provided with the air intake port 1 and the air exhaust port 2 is not shown and is shown by a chain line. Reference numeral 4 is a synthetic resin nonwoven fabric sheet having ventilation and water permeability. Far-infrared radiating substance ultrafine particles are adhered to the sheet 4 in a dosage form to form a far-infrared radiating layer 5, and the sheet 4 is formed into a wavy ring. And is attached to the hollow annular plates 6 and 6 ', and is supported by a porous annular band plate 7 that is erected inside the inner peripheral ends of the annular plates 6 and 6'and the air element 8 is formed. There is. The sheet 4 is attached to the annular plates 6 and 6'for reinforcement, and is glued to the inner surface of each annular plate. The air element 8 is housed in the annular container 3 and constitutes the fluid purifying device of the present invention. The far infrared radiation layer 5 may be formed in the form of a coating agent or a dipping agent. Alternatively, when the sheet 4 is formed by a paper container, a breathable water-permeable synthetic resin nonwoven fabric sheet having a far infrared radiation layer may be attached to the paper container sheet 4. FIG. 3 is a partial crushing plan view of an air element in an air purification apparatus for an automobile in another embodiment, and FIG. 4 is a half cutaway view thereof. An annular container provided with an air inlet and an air outlet is not shown. Reference numeral 9 is a foamable synthetic resin ring body having ventilation and water permeability, and far-infrared ray emitting layer 5 is formed by attaching ultrafine particles of far-infrared radiation substance to the outer peripheral surface and the inner peripheral surface of the ring body 9 as a containing agent. The breathable and water-permeable synthetic resin nonwoven fabric sheets 4 and 4'are closely attached to each other, are attached to the hollow annular plates 6 and 6 ', and are erected inside the inner peripheral ends of the annular plates 6 and 6'. An air element 8 is formed by being supported by a ring-shaped strip 7 having the property. The expandable synthetic resin ring 9 adhered to the annular plates 6 and 6'for reinforcement is glued to the inside of each annular plate. The air element 9 is housed in the annular container 3 and constitutes the fluid purifying device of the present invention. The synthetic resin non-woven fabric sheet 4 on which the far-infrared radiation layer is formed and the expandable synthetic resin ring 9 are replaced with only the far-infrared radiation synthetic resin non-woven fabric sheet 13 shown in FIG. 6 or 7 to wind the annular plates 6 and 6 ′. It may be glued and accommodated in between. FIG. 5 is a plan view of the air element 8 used in the air cleaner and the air conditioner. Illustration of other components provided with an air intake port and an air exhaust port is omitted. Reference numeral 10 denotes a frame of an air element, and a synthetic resin nonwoven fabric sheet 11 having a far infrared radiation layer 5 formed thereon is stretched on the frame 10 to form an air element 8. The air element 8 is installed close to the air intake port or the air exhaust port to form a fluid purification device. 6 and 7 show the far-infrared radiation synthetic resin non-woven fabric in which the far-infrared radiation ultrafine particles 12 are adhered to the sheet 11 in the form of an impregnating agent on the synthetic resin non-woven fabric sheet 11 in the above embodiment to form the far-infrared radiation layer 5. In the partially cutaway view of the sheet 13, which is shown in FIG. 7, the far-infrared radiation layer 5 is formed on the synthetic resin nonwoven fabric sheet 11 with the far-infrared ultrafine particles 12 as a coating agent. These far infrared radiation synthetic resin nonwoven fabric sheets 13 are used in the above-mentioned embodiment. FIG. 8 is a half sectional view of a fluid purifying device according to another embodiment. Any one of a synthetic resin fiber group, a plant fiber group, a glass fiber group, or a composite thereof in which a far-infrared radiation layer 5 is formed in a cylindrical container 14 provided with a fluid intake 1 and a fluid outlet 2. Form a fluid element by mixing a group of non-ferrous metal strips such as stainless steel and aluminum in the group. In this embodiment, the glass fiber group 15 and the metal strip group 16 are mixed. Adapted to the activation of purification of hot air and hot water. The material of which the element is made is selected according to the application of the fluid purification device. The mixture of metal pieces is an essential requirement, because each metal piece absorbs heat, radiates heat, and reflects heat, and the far infrared rays are amplified and radiated, so that the emissivity of far infrared radiation generated from the metal pieces is improved.

[0007]

[Effect of device]

 Next, a peculiar effect of far infrared radiation will be abbreviated. There are many far-infrared radiation materials, but they have excellent radiation efficiency, and the commonly used radiation materials are fine ceramics, metal oxides, carbons, natural stones Otani stone, barite stone, and zeolite. Systems etc. exist. Although it may be used alone, a composite material of the above-mentioned radioactive material is used. In the natural world, these far-infrared radiation materials radiate far-infrared radiation from themselves even at room temperature, but the far-infrared radiation material absorbs heat and emits heat by solar heat, warm air, or an appropriate heating means. If the radiation means is adapted, far infrared rays can be emitted more efficiently. However, proper irradiation of far-infrared rays belonging to the long wavelength region has a favorable effect on water or animals and plants. This radiation has an affinity and an attractiveness to water, and although there are unconfirmed reasons, it is effectively used to activate water molecules and cell tissues. Normally, the wavelength of far-infrared radiation emitted from far-infrared radiation materials at room temperature, such as sunlight and warm air, varies depending on the quality, quantity, radiation area, intensity of light and heat of the radiation material. It is about 50 microns. This unique action of far infrared radiation reduces the water molecule population of the activated material. It has the effects of increasing the amount of dissolved nitrogen, reducing harmful organic substances, antioxidant, deodorizing, antibacterial and other unconfirmed effects. Therefore, also in the present invention, the far-infrared emitting layer is formed by using the far-infrared emitting material selected from the far-infrared emitting materials and having excellent radiation efficiency. In a fluid purification device attached to an automobile engine, a combustion engine, etc., air is first purified in a filter layer inside the device. In the fluid purification device of the present invention, the far infrared rays are amplified and radiated by the forced airflow and the abrasion of the far infrared ray emitting surface to activate the water molecules in the air. Air with high oxygen concentration is supplied, combustion efficiency is improved, and emission of harmful organic substances is reduced. In particular, the catalytic reaction of harmful organic substances of nitrogen oxides declines, and the emission amount of nitrogen oxides decreases. In addition, by installing the fluid purifying device of the present invention for other fluids such as water and oils, such substances can be purified and activated by the peculiar action of far infrared radiation.

[0008]

[Brief description of drawings]

FIG. 1 is a partial crushing plan view of an embodiment of the present invention.

FIG. 2 is a side view of FIG.

FIG. 3 is a partially crushed plan view of another embodiment. (Fluid element)

FIG. 4 is a half sectional view of FIG. (Fluid element)

FIG. 5 is a plan view of another embodiment. (Fluid element)

FIG. 6 is a partial cutaway view of a far infrared radiation synthetic resin nonwoven fabric sheet.

FIG. 7 is a partial cutaway view of a far infrared radiation synthetic resin nonwoven fabric sheet.

[Explanation of symbols]

 1-air intake port 2-air discharge port 3-annular container 4-synthetic resin nonwoven fabric sheet 5 far-infrared radiation layer 6-annular plate 7-annular strip plate 8-air element 9-expandable synthetic resin annulus 10 Frame 11-Synthetic resin nonwoven fabric sheet 12-Far-infrared emitting substance ultrafine particles 13-Far-infrared emitting synthetic resin nonwoven fabric sheet 14-Cylinder 15-Glass fiber group 16-Metal strip group

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] July 11, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Brief description of the drawing

[Correction method] Change

[Correction content]

[Brief description of drawings]

FIG. 1 is a partial crushing plan view of an embodiment of the present invention.

FIG. 2 is a side view of FIG.

FIG. 3 is a partially crushed plan view of another embodiment. (Fluid element)

FIG. 4 is a half sectional view of FIG. (Fluid element)

FIG. 5 is a plan view of another embodiment. (Fluid element)

FIG. 6 is a partial cutaway view of a far infrared radiation synthetic resin nonwoven fabric sheet.

FIG. 7 is a partial cutaway view of a far infrared radiation synthetic resin nonwoven fabric sheet.

FIG. 8 is a half sectional view of another embodiment.

[Explanation of reference numerals] 1-air intake port 2-air discharge port 3-annular container 4-synthetic resin nonwoven fabric sheet 5-far-infrared radiation layer 6-annular plate 7-annular strip plate 8-air element 9-foaming synthetic Resin ring body 10-Frame body 11-Synthetic resin non-woven fabric sheet 12-Far infrared radiating substance ultrafine particles 13-Far infrared radiation synthetic resin non-woven fabric sheet 14-Cylindrical container 15-Glass fiber group 16-Metal strip group

Claims (6)

[Scope of utility model registration request] 1. A fluid element in which a far-infrared radiation layer made of a far-infrared radiation substance is contained, coated, dipped or attached in a container provided with a fluid intake port and a fluid discharge port, A fluid purification device characterized in that the fluid passing through the fluid element is activated by purification. 2. A far-infrared radiation layer is formed on a paper container or synthetic resin non-woven fabric sheet having ventilation and water permeability, and the far-infrared radiation layer is formed into a hollow corrugated ring body to form a fluid element housed in a hollow annular container. The fluid purifying apparatus according to claim 1, characterized in that 3. A breathable synthetic resin nonwoven fabric sheet having a far-infrared radiation layer formed on the outer peripheral surface, the inner peripheral surface or both side peripheral surfaces of a foamable synthetic resin ring body having a breathable water permeability is closely attached. The fluid purification device according to claim 1, wherein a fluid element housed in a hollow annular container is formed. 4. The fluid purifying apparatus according to claim 1, wherein the far-infrared radiation synthetic resin nonwoven fabric sheet having ventilation and water permeability is formed in a hollow annular container to form a fluid element. . 5. A fluid element in which a far-infrared radiation layer is formed on a sheet made of synthetic resin non-woven fabric having ventilation and water permeability is attached to a frame body, and a fluid element is installed near a fluid intake port or a fluid discharge port. The fluid purifying apparatus according to claim 1, wherein 6. A fluid element in which a far-infrared radiation layer is formed on a synthetic resin fiber, a plant fiber, a glass fiber, an aggregate of metal strips or an aggregate of these composites has a fluid intake port and a fluid exhaust port. The fluid purifying apparatus according to claim 1, wherein the fluid purifying apparatus is stored in a provided container.