KR20030059602A - Electro-Conductive Heating Mortar using Graphite and Nonorganic Binder - Google Patents

Abstract

PURPOSE: Provided is an exothermic mortar with electric conductivity, heat insulation, humidity control, far infrared emission and strength by using graphite, inorganic binder(yellow earth, cement), additives(ferric oxide, alumina) and minerals (elvan, jade). CONSTITUTION: The exothermic mortar comprises 20-70wt.% of graphite, 30-50wt.% of inorganic binder such as yellow earth, cement or silica, 0-30wt.% of additive such as Zn, Al2O3 or Fe2O3 for strength and durability, and 25-30wt.% of auxiliary materials such as elvan, germanium, jade, quartz, etc. for heat insulation, humidity control and far infrared emission. The heat generating matter(plate, 100) is produced by plastering exothermic mortar on the structure, setting one or more electrodes(200a, 200b) on the ends of the structure, and connecting power to the structure.

Description

Electro-Conductive Heating Mortar using Graphite and Nonorganic Binder}

The present invention is a hydraulic pyrogenic mortar containing graphite, loess, minerals or rocks. Specifically, graphite, ocher, minerals or rocks are dried and sorted to an ideal particle size according to the application, and these are mixed in a predetermined ratio. By pouring only water in the immediate use to increase the convenience of producing a heating element using a heating mortar. An electrically conductive heating mortar using graphite and an inorganic binder, which is characterized by producing a heating element using a heating mortar and installing at least one or more pairs of electrodes at both ends of the heating element and flowing a low pressure direct current harmless to a human body.

In other words, mortar powder is prepared by mixing graphite, loess, mineral or rock, and then separately prepared by solidifying binder and mixed with water to generate heat through electricity by using the electrical conductivity of graphite, The present invention relates to an exothermic mortar having excellent compressive strength, tensile strength and durability, as well as far-infrared radiation effect due to thermal insulation, humidity control, and heat storage of minerals or rock components.

In the prior art, ondol is used for heating the floor of the building, and Ondol is recognized for its excellence as a unique heating method of our country, but existing hot water ondol has low construction efficiency and low energy efficiency due to the complex construction of the site. In addition, it is not only inconvenient for maintenance, but also has disadvantages such as requiring a hot water pipe, which is expensive and a heat transportation facility, such as a boiler or heater as a heat source facility.

Although a regenerative electric ondol that can use midnight electricity has been developed, it generates heat when a high voltage alternating current is used as a power source to heat the heater, which may cause electric shock due to high voltage electricity. The electromagnetic field generated mainly in the body is harmful to the human body and consumes a lot of power, so the heating cost is relatively high.

Ocher is a material that has been used traditionally for construction. It is used for plastering or wall by mixing straw straw agar lime with ocher in the traditional way. In recent years, it has been common practice to mix cement or industrial bond binders with ocher to increase the crack prevention strength.

Elvan, germanium, jade, and crystal have been proven to emit far infrared rays, which are beneficial to the human body when the temperature is increased, and these are widely applied to household goods such as beds, radiators, and mattresses.

The present invention provides an electrically conductive heating mortar to produce a heating element, and generates heat through electricity by using the electrical conductivity of graphite, the far-infrared radiation effect by thermal insulation, humidity control, heat storage of loess, mineral or rock powder In addition, by using the compressive strength, tensile strength and durability, etc. provides a heat-generating mortar that can easily produce a heating material that can be applied to the improvement of the heating environment or production facilities.

Graphite, loess, mineral or rock is dried and selected to make the ideal particle size according to the application, and the mixture is mixed at a predetermined ratio to produce exothermic mortar. In the field, only the amount of water indicated on the exothermic mortar is poured and mixed immediately. It improves the convenience and efficiency of manufacturing heating elements using exothermic mortar. If necessary, a separate solidified binder may be prepared and mixed with the exothermic mortar to increase the structural strength of the exothermic body.

In the process of manufacturing the heating element, at least one pair of electrodes are installed at both ends of the heating element so that the power source can be connected to the heating element, and a low pressure direct current that is harmless to the human body is allowed to generate heat.

Graphite is used to ensure that the heating element retains electrical conductivity, and ocher, cement, or silica-based binders can be used as inorganic binders, and the structural strength of the heating element is ensured by mixing additive materials that enhance the adhesion of the heating mortar. In order to enhance far-infrared radiation, a mixture of calcite or germanium, jade, and crystals should be added.

The exothermic mortar of the present invention is excellent in the heat generation efficiency even when flowing electricity at low pressure to be harmless to humans or animals, has a stable stability does not change the physical properties of the heating element at high temperature and excellent durability even if repeated heating and cooling for a long time Ensure that exothermicity is maintained continuously.

The heat generating mortar of the present invention can be used as a floor material of a building, and requires expensive heat source equipment and heat transportation equipment along with complex on-site construction properties, low energy efficiency, and maintenance inconveniences as in the conventional hot water ondol. In the present invention by improving the weakness, such a heat source equipment and a heat transportation equipment is unnecessary, so as to generate heat directly to the heating element by electricity to improve the workability, increase the energy efficiency, and eliminate the inconvenience of maintenance.

In the case of manufacturing the heating material or heating material using the present invention, since the mortar is applied in an arbitrary shape according to the geometrical structure of the structure, it is not necessary to perform additional processes such as a series of hot water piping work or electrical wiring work, thereby reducing the construction cost. Significantly reduce

If the heating element is manufactured and heated using the electrically conductive mortar, the heating cost is lower than that of the existing hot water ondol heating, and the clean energy is used to reduce the environmental pollution.

1 is a perspective view showing a structure of a room in which a plate-shaped heating element 100 manufactured using a heating mortar of the present invention as a heating material, as an embodiment according to the present invention, for convenience and wall of the front and right sides of the wall 600. The illustration is omitted in the figure, simply install the plate-like heating element 100 on the existing or new floor slab 500, and installed a pair or more of the electrodes (200a, 200b) and will generate heat. The plate covering the plate heating element 100 is shown to be partly rolled up for better understanding.

100 plate heating element 200a anode electrode

200b cathode electrode 210a anode wire

210b Cathode Wire 220 Voltage Regulator

300 Temperature sensor 310 Temperature sensor lead wire

320 Temperature Indicator 500 Floor Slab

600 Wall 700 Sheets

In order to achieve the above object, the present invention provides an electrically conductive heating mortar to easily produce a heating element, and generates heat through electricity by using the electrical conductivity of graphite, and keeps warmth and humidity of ocher, mineral or rock powder. Conductive heating using graphite and inorganic binders to produce heating materials that can be applied to the improvement of residential environment or production facilities by securing the compressive strength, tensile strength and durability as well as the far-infrared radiation effect by control and heat storage. Provide mortar.

Exothermic mortar of the present invention is composed of 20 to 70% by weight of graphite, 50 to 30% by weight of the inorganic binder, 0 to 30% by weight of the additive material and 25 to 30% by weight of the auxiliary material, 50 to 65% by weight of the solid component Mixing, kneading, molding, curing and solidifying water can produce a heating element, and it contains graphite with electric conductivity that generates heat when electricity is supplied to the electrode installed in the heating element, and uses ocher, cement or silica as an inorganic binder. To produce heating elements, zinc, aluminum oxide or iron oxide, etc. by using additional materials to ensure the heat generation, structural strength and durability of the heating elements, and using alumina, germanium, jade, crystals as an auxiliary material to keep them warm, It provides an electrically conductive exothermic mortar using graphite and inorganic binder, characterized in that the far-infrared radiation effect by humidity control, heat storage.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of heating the building using the heat generating mortar of the present invention.

1 is a perspective view showing a structure of a room in which a plate-shaped heating element 100 manufactured using a heating mortar of the present invention as a heating material, as an embodiment according to the present invention, for convenience and wall of the front and right sides of the wall 600. Are omitted from the figure.

Plate-like heating element 100 using the heating mortar is usually installed on the floor slab 500 and the living plate 700 is laid on the plate-like heating element 100. The stencil 700 is shown as partly rolled up to help understanding the perspective view.

The plate heating element 100 generates heat by flowing low voltage DC electricity, and connects the positive electrode of DC through the voltage regulator 200 to the positive electrode 200a through the positive electrode 210a and the negative electrode through the negative electrode 210b. When connected to the cathode electrode 200b, a direct current flows from the anode electrode 200a to the cathode electrode 200b and generates heat due to the electrical resistance of the plate heating element 100.

The heat generated temperature is sensed by the temperature sensor 300 and is displayed on the temperature indicator 320 through the temperature sensor lead line 310 it can be seen the temperature of the plate heating element (100).

The temperature of the plate heating element 100 may be adjusted to a predetermined temperature by adjusting the voltage of the DC power supply with a voltage regulator 220.

The electrically conductive exothermic mortar using the graphite and the inorganic binder of the present invention is not limited thereto and may be configured in various shapes and methods.

In the present invention, using the electrically conductive heating mortar provided, it is possible to conveniently produce a heating element, by using the electrical conductivity of graphite to generate a low-pressure direct current electricity through the heating element, loess, mineral or rock powder contained in the heating mortar It is beneficial to users by increasing the far-infrared radiation effect due to heat retention, humidity control, and heat storage, and it can be applied to improvement of heating materials for heating of residential environment or production facility by using compressive strength, tensile strength and durability.

Graphite, ocher, mineral or rock are dried and sorted to an ideal particle size according to the application, and these are pre-mixed and supplied at a predetermined ratio.On the spot, only water is poured into the exothermic mortar so that it can be used immediately. It can be manufactured and the work of mixing the mortar in the field can be omitted, thereby increasing the efficiency of the heating element manufacturing.

In the process of manufacturing the heating element, at least one pair of linear electrodes are installed at both ends so that the power source can be connected to the heating element. The electromagnetic field generated by the energization process is harmless to people or animals.

The exothermic mortar of the present invention is excellent in heat generating efficiency even when flowing electricity at low pressure, has a stable stability does not change the physical properties of the heating element at high temperature, and excellent durability even if repeated heating and cooling for a long time can be continuously maintained heat generation have.

When the heating mortar of the present invention is used as a flooring material of a building, and yellow soil is used as the inorganic binder, when the heating element made of the heating mortar generates heat, far-infrared rays which are beneficial to the human body are emitted from the heating element, and mixed with elvan, germanium, jade, and crystal. When it is possible to increase the emission of far infrared rays, far-infrared rays penetrate deeply into the body of a person or animal to use it to release waste products through sweat and increase body temperature to increase disease resistance.

Conventional hot water ondol has the disadvantages such as complicated on-site construction, low energy efficiency, inconvenient maintenance, and high heat source facilities such as boilers and heaters, and requiring heat transportation facilities such as hot water pipes. Since expensive oil is usually used as a fuel, a lot of heating costs are required, but in the present invention, such a heat source facility and a heat transportation facility are unnecessary, and simply generate heat by simply passing electricity to a heating element, thereby reducing equipment cost, maintenance cost, and heating cost. Can be.

In the case of manufacturing the heating material or heating material using the present invention, since the mortar is applied in an arbitrary shape according to the geometrical structure of the structure, it is not necessary to perform additional processes such as a series of hot water piping work or electrical wiring work, thereby reducing the construction cost. It can greatly reduce.

Even when installed on the floor of an existing building simply remove the heating mortar and simply install the heating mortar on the existing slab, it is possible to simply improve the conventional heating method using the heating mortar of the present invention.

Heating using electrically conductive heating mortar reduces the environmental pollution in residential areas by using clean energy because it generates heat using electricity, unlike existing hot water heating, which uses oil as fuel to contaminate the environment of residential areas.

The present invention can be used for residential heating such as floor and wall heating of buildings, radiators for heating, and can be used for heating devices such as heat storage water heaters, heaters, kitchen stoves, warmers, etc., as well as snow runways, lamps, bridges and roads. Or for use for ice making or the like.

Claims (3)

Exothermic mortar of the present invention is composed of 20 to 70% by weight of graphite, 50 to 30% by weight of the inorganic binder, 0 to 30% by weight of the additive material and 25 to 30% by weight of the auxiliary material, 50 to 65% by weight of the solid component When water is mixed and kneaded and cured into mortar, it can be produced as a heating element.The heating mortar contains graphite having electric conductivity that generates heat when electricity is used, and is produced as a heating element using ocher, cement or silica as an inorganic binder. By using zinc, aluminum oxide and iron oxide as additives, it ensures the exothermicity, structural strength and durability of the heating element, and uses the rock powders of elvan, germanium, jade and crystal as auxiliary materials to control their heat insulation, humidity control and heat storage. Electroconductive exothermic mortar using graphite and inorganic binder, characterized in that to increase the far infrared radiation effect According to claim 1, in order to manufacture the heating element, only the mortar is applied to the geometrical structure of the heating target facility, so in order to produce a heating material or heating material, an additional process such as a series of hot water piping work or electrical wiring work is performed. It is not necessary, even in the case of installing the heating element in the existing structure, simply install the heating mortar in the shape of the existing facility, the graphite and inorganic binder, characterized in that it can simply improve the conventional heating method Electrically conductive exothermic mortar The heat generating efficiency according to claim 2, wherein a heat generating mortar is installed in a heat generating target facility in order to manufacture a heat generating element, at least one pair of electrodes are installed at both ends of the heat generating element, and a power source is connected to the heat generating element to generate heat, and heat is generated at low pressure through the heating element. It has excellent stability, which does not change the physical properties of the heating element at high temperature, excellent durability even after repeated heating and cooling for a long time, and continuously generates heat generation electrically conductive exothermic mortar using graphite and inorganic binder