KR20020070012A - The far infra red ray emissive cup and method for it's preparation. - Google Patents

Abstract

PURPOSE: A ceramic cup(bowl) with a far infrared emitting body on its bottom is provided to make sharp tastes of a drink be mild and soft. CONSTITUTION: The manufacturing method of ceramic cup is as follows: mixing 20wt.% of clay, 60wt.% of kaolin, 10wt.% of feldspar, and 10wt.% of silica; adding water to make a dough; forming and drying the dough at 45-55 deg.C for 24hrs.; sintering it at 1200-1300deg.C for 8hrs.; cooling it to 200deg.C in the furnace and to room temperature in the air; glazing it with a liquid, as a binder, including MnO2, Fe2O3, Cr2O3, CuO and CoO; inserting a far infrared emitting body(102) into a groove formed on the bottom of a cup(101); drying it at 45-55deg.C for 24hrs.; sintering it at 1176-1220deg.C. The far infrared emitting body is produced by the following steps of: mixing raw materials such as 80-85wt.% of Fe2O3, 9-15wt.% of MnO2, 8-10wt.% of ZnO, 2-5wt.% of Al2O3, 1-3wt.% of SiO2, 3-3.5wt.% of CuO, 2.5-5wt.% of CaO, 2.5-4wt.% of CoO, 1.5-2wt.% of MoO3 and 0.2-0.5wt.% of Y2O3; spray drying the mixture to form granules(<=1micrometer); forming it under pressure of 1200-1500kg/cm¬2; heating it to 1300deg.C in inert gas atmosphere and holding it at 1300deg.C for 4hrs. in N2 atmosphere; furnace cooling it to 200deg.C in inert gas atmosphere and then air cooling.

Description

The far infra red ray emissive cup and method for it's preparation.

The present invention relates to a ceramic cup (cup) that emits high efficiency far infrared rays and a method of manufacturing the same. More specifically, when a drink made of coffee and other liquids and an irritating liquid such as laxative are put into a ceramic cup (glass) where far-infrared radiation is emitted, the far-infrared radiation emitted from the cup (glass) acts on the water molecules and causes the beverage itself. The present invention relates to a method of manufacturing a ceramic cup that emits far-infrared rays, which can alleviate strong irritation and give a mild and soft taste.

Conventional ceramic cups are simple magnetic or ceramic cups, which are mixed with the following powders of minerals according to their proportions, kneaded with water, and then molded, and then fired from 1050 ° C to 1150 ° C to 1200 ° C to 1300 ° C. To make porcelain cups and porcelain cups.

The mixing ratio of raw materials of ceramic cups is largely divided into four types: (1) kaolin 80 wt%, feldspar 10 wt%, quartzite 10 wt%, (2) kaolin 40 wt%, feldspar 50 wt%, silica 10 % By weight, (3) 40% by weight of kaolin, 30% by weight of feldspar, 30% by weight of quartz, (4) 40% by weight of kaolin, 10% by weight of feldspar, 50% by weight of quartz. (1) clay 20% by weight, kaolin 60% by weight, feldspar 10% by weight, quartzite 10% by weight, (2) clay 20% by weight, kaolin 20% by weight, feldspar 50% by weight, silica 10% by weight (3) is 20% by weight clay, 20% by weight kaolin, 30% by weight feldspar, 30% by weight quartz, 4 is 20% by weight clay, 20% by weight kaolin, 10% by weight feldspar and 50% by weight quartz.

In this way, water was added to the blended raw materials to be molded, dried in a drying chamber at 45 ° C. to 55 ° C., and then loaded into a kiln, and the temperature in the kiln was maintained at 1050 ° C. to 1150 ° C. or 1200 ° C. to 1300 ° C., depending on the raw material, for 7 hours. It is calcined over 8 hours, cooled slowly until the temperature in the furnace reaches 200 ° C., and then the product is taken out of the kiln and cooled.

Glaze the cooled product, dry it, load it into the kiln again, and fire in the same way as above. The product (cup) made in this way is a cup that does not emit far infrared rays, so it does not cause any change in the contents of the cup, that is, coffee and other irritating drinks or brews, so it sometimes tastes too bitter or disgusting. will be.

Therefore, the present invention can be soft and gentle and comfortable drinker without feeling uncomfortable when taking a drink, tea and medicinal herbs using a cup (glass) that is far-infrared radiation to solve the problems of the conventional cup In addition, it is an object of the present invention to provide a method for manufacturing a cup (cup) which allows to enjoy the original tea taste as it is.

.

(Figure 1)

101: ceramic cup with far infrared radiation

102: far infrared emitter ceramics

(Figure 2)

201: Cup without Far Infrared Emitter Ceramics

202: cup with far infrared emitter ceramics

203: Bottom groove of the cup for fitting the far infrared emitter ceramics

In the present invention, the mineral powder of 20% by weight of clay, 60% by weight of kaolin, 10% by weight of feldspar, 10% by weight of quartz is placed in a mixer, mixed evenly, and then poured into a prescribed amount of water, kneaded, and then molded and then heated to 45 ° C. to 55 ° C. It is dried in a drying room for 24 hours.

The completely dried molded product is placed in a kiln and fired for 8 hours at a furnace temperature of 1200 ° C to 1300 ° C. The furnace is cooled slowly until the temperature reaches 200 ° C. Then, the furnace door is opened and the product is taken out and cooled at room temperature. Let's do it.

After the first firing, the molded body is converted into _{3.0 to} 3.5% by weight of transition elements such as manganese dioxide (MnO ₂ ), iron oxide (Fe ₂ O ₃ ), chromium oxide (Cr ₂ O ₃ ), cobalt oxide (CoO), and copper oxide (CuO). And feldspar 29 to 30.5 wt%, tolomite 5.5 to 6.2 wt%, limestone 9.2 to 9.7 wt%, galvanized 5.5 to 6.0 wt%, plastic clay 4.5 to 5.0 wt%, quartz 26 to 28 wt%, aluminum oxide 1.2 to 1.6 Applying glaze composed of 0.3% by weight and 0.5% by weight of chromium, and then insert the far-infrared radiator 102 prepared in advance to the bottom 203 inside the cup, and dried over 24 hours in a drying chamber of 45 ℃ to 55 ℃.

The first firing, glazing and the product with the far-infrared radiator 102 are loaded into the firing furnace and fired for 8 hours at a furnace temperature of 1176 ° C to l220 ° C and gradually cooled until the temperature inside the furnace reaches 200 ° C. After opening the kiln door, the product is taken out and cooled to room temperature.

When described in more detail the far-infrared radiator 102 used in the product as follows.

The cast product of the far-infrared radiator 102 ceramic and its mixing ratio are 80 to 85% by weight of iron oxide (Fe ₂ O ₃ ), 9-15% by weight of manganese dioxide (MnO ₂ ), 8 to 10% by weight of zinc oxide (ZnO), and oxidation Aluminum (Al ₂ O ₃ ), 2 to 5% by weight, silicon oxide (SiO ₂ ) 1 to 3% by weight, and the dependent materials include copper oxide (CuO) 3 to 3.5% by weight, calcium oxide (CaO) 2.5 to 5, Cobalt oxide (CoO) 2.5 to 4% by weight, molybdenum oxide (MnO ₃ ) 1.5 to ₂ % by weight and yttrium oxide (y ₂ O ₃ ) 0.2 to 0.5% by weight.

The above-mentioned mineral powder is put into a mixer, mixed evenly, and then spray-dried to make granular powder having a particle size of 1 μm or less. The ceramic composition is molded in a mold at a pressure of 1200 kg / cm 2 to 1500 kg / cm 2 to finally obtain the desired shape. The molded body is placed in a closed furnace, and the furnace temperature is gradually raised in a ball active gas atmosphere over 9 hours, and when the furnace temperature reaches 1300 ° C., the furnace temperature of 1300 ° C. is maintained at about 4 hours in a nitrogen atmosphere for efficient sintering.

After sintering, maintain the temperature in the kiln for about 4 hours. After sintering, the temperature in the kiln is gradually lowered from 1300 ℃ to 200 ℃. At this time, it is gradually cooled while inert gas (nitrogen or helium gas) is injected into the kiln again. When the furnace temperature reaches about 200 ° C, the injection of nitrogen is stopped and the sintered body is slowly cooled at room temperature.

The present invention is a glaze composition of transition elements such as manganese dioxide (MnO ₂ ), iron oxide (Fe ₂ O ₃ ), chromium oxide (Cr ₂ O ₃ ), cobalt oxide (CoO), copper oxide (CuO) in order to make a highly efficient infrared emitter In addition, the far-infrared radiator was contacted to the bottom of the glazed cup so as to be fired again so that the glaze acts as a binder for bonding the cup 101 and the far-infrared radiator 102.

The far-infrared radiation cup 101 of the present invention is a high-purity far-infrared radiation ceramic cup (cup), which is a cup of the present invention when drinking coffee, as well as other irritating drinks or decoctions, etc. It not only activates the water molecules of water, the main substance of bitter decoction, to soften the taste of coffee, but also relieves the bitter taste of other irritating drinks or bitter decoction so that the drinker can drink without feeling disgust or irritation. It does not change the dissolved contents or chemical reactions due to the activation of water molecules, and does not change the quality of the contents dissolved in water, and the activation of water molecules has the effect of drinking healthy water and living water.

Example 1

The composition and proportion of the far-infrared ceramic cup 101 are mixed with 20% by weight of clay, 60% by weight of kaolin, 10% by weight of feldspar, and 10% by weight of silica. In order to obtain a molded article, one piece was put in a mold and molded at a pressure of 1300 kg / cm 2 to 1500 kg / cm 2, followed by demolding the obtained molded body, and then attaching a handle obtained in the same manner, followed by drying in a drying chamber at 45 ° C. to 55 ° C. for 24 hours. .

The dried compacts are loaded into a kiln, fired at 1200 ° C to 1300 ° C for 8 hours, and when the furnace temperature reaches 200 ° C, they are taken out of the furnace and gradually cooled at room temperature.

3.5 wt% of transition elements such as manganese dioxide (MnO ₂ ), iron oxide (Fe ₂ O ₃ ), chromium oxide (Cr ₂ O ₃ ), cobalt oxide (CoO), copper oxide (CuO), etc. %, 29% feldspar, 5.5% tolomite, 9.2% limestone, 5.5% galvanized, 4.5% plastic clay, 26% quartz, 1.2% aluminum oxide, 5.5% tin oxide, 6.0% clay , Immersed in a glaze consisting of 0.3% by weight of chromium and 30% by weight of water, completely glazed to the outside, and then put a separately prepared far-infrared radiator 102 into a groove 203 provided on the bottom of the inner surface of the glazed cup, and then 45 ° C. to After drying for 24 hours in a drying chamber at 55 ° C., it is put in a kiln again and fired at a temperature of 1176 ° C. to 1220 ° C. for 8 hours. When the furnace temperature reaches 200 ° C., it is taken out of the furnace and gradually cooled at room temperature to radiate far infrared rays. 101

Example 2

The far-infrared radiator 102 prepared in Example 1 is a far-infrared radiator 102 obtained by the method described in the constituent section of the present invention with a mineral formed of the cast material and the dependent composition as described in the [Structure of the Invention] section. It is designed to fit into the groove provided on the bottom, and the results of measuring the emissivity and radiation dose of far infrared rays are as follows.

Measuring Institution: Korea Institute of Construction Materials Testing and Research (Application Center for Far Infrared)

※ Attachment: Emissivity and radiation output measurement result graph --- 1 sheet

Claims (3)

Manganese dioxide (MnO ₂ ), iron oxide (Fe ₂ O ₃ ), chromium oxide (Cr ₂ O ₃ ), in a ceramic glass composed of 20% by weight of clay, 60% by weight of kaolin, 10% by weight of feldspar and 10% by weight of quartz 3.5 wt% of transition elements such as cobalt oxide (CoO) and copper oxide (CuO), 29 wt% of feldspar, 5.5 wt% of tolomite, 9.2 wt% of limestone, 5.5 wt% of zinc, 4.5 wt% of plastic clay, 26 wt% of quartz, Preparation of ceramic cup (glass) that emits far infrared rays by applying glaze consisting of 1.2% by weight of aluminum oxide, 5.5% by weight of tin oxide, 6.0% by weight of clay, 0.3% by weight of chromium and 30% by weight of water Way Method of manufacturing a ceramic cup (glass) that emits far-infrared rays of high efficiency by fitting a far infrared radiator into a groove provided on the bottom of the ceramic cup of claim 1 Method of manufacturing a ceramic cup (glass) that emits far-infrared rays, characterized in that the use of a binder by glazing in fitting the far-infrared radiator to the groove provided on the bottom of the ceramic cup of claim 1