KR200328050Y1 - A laying box of carbon molding body structure - Google Patents

Abstract

The present invention relates to the ossuary of the carbon molded structure, and the ossuary is made of the carbon molded body composed mainly of charcoal in fine powder, so that the inorganic components contained in the char and the functions of the charcoal, the far infrared radiation function, the anion emitting function, the humidity control function, and Its purpose is to prevent corruption of the ashes by preventing condensation (moisture) from inside the ossuary. The present invention constituted for this purpose is an oscapal container 110 capable of storing the ashes 10 in the internal space 114 through the ashes inlet 112 of the upper side, and an inner lid 120 that opens and closes the ashes inlet 112. ) And the oscapal container 110 consisting of the outer lid 130 to open and close the entire upper part, the ossuary container 110, the inner lid 120 and the outer lid 130 are made of fine powder charcoal as a main component It consists of the structure of carbon molding.

Description

A laying box of carbon molding body structure

The present invention relates to the ossuary of the carbon molded structure, and more particularly, the ossuary to inject the ashes after the cremation of the body is molded into a carbon molded structure made of a carbon molded body composed of fine powder charcoal. It is about.

In general, when a person dies, the burial or cremation is buried according to a funeral procedure.In the meantime, the custom of making and burying graves through funeral coffins can be widely practiced. It is a well-known fact. Of course, these burial customs are still the mainstream of funerals.

Recently, the graveyard culture of cremation of the body is highly recommended as the graveyard has caused various problems due to the erosion and burial of the land as a social problem. The cremation culture following the cremation is being expanded as the crevices are set up in various regions with the promotion and recommendation of the government and various social organizations.

As described above, during cremation of the body, the ashes generated by cremation are generally placed in the ossuary and placed in the ossuary.

On the other hand, the ossuary is a jar that puts bones after cremating the body of a person, and is also called a lagoon, a crypt and a long bone container. The crustacean is made of metal, ceramics, stone, glass, wood, etc. as its main materials, and there are various shapes such as the shape of a person's face or a house.

Although the number of containers forming the crypt is not constant, the configuration of the container containing the container and the container directly containing the cremated bone is the most basic, and only one container or 3 to 6 small containers in the container. You can also put two or two bone complexes piled up and down.

However, since the crypts according to the prior art are made of metal, ceramics, stone, glass, wood, etc., condensation (humidity) occurs inside the ashes, and the ashes put inside the crypts decay, resulting in odors and insects. There is a problem that the back. That is, when the ashes are stored in the ossuary box according to the prior art, if the temperature drops sharply when the temperature difference is severe, condensation (humidity) forms on the inner wall when the water vapor in the inside of the urine box comes into contact with the inner wall of the cold box. There is a problem that occurs.

Therefore, condensation (humidity) generated inside the ossuary box flows down to the ashes and is mixed with the ashes, causing the ashes to naturally deteriorate or decay over time. That is, there is a problem that the long-term storage of ashes powder is difficult.

The present invention was devised to solve the problems as described above, by making the ossuary in the carbon molding structure of the fine powder of charcoal as the main raw material, the far-infrared radiation function, the negative ion release function, The purpose of the present invention is to provide a carbon box structure that prevents condensation (humidity) from occurring inside the ossuary box through humidity control function and anti-corruption function.

In addition, another object of the present invention is to prevent the condensation (humidity) phenomenon inside the bin box through the inorganic components and the charcoal function of far-infrared radiation function, anion release function, humidity control function and anti-corruption function of the charcoal box of the carbon molding structure By preventing the decay of the ashes, the long-term preservation of the ashes is possible.

1 is an exploded perspective view showing the ossuary of the carbon molded structure according to the present invention.

Figure 2 is a front view showing the union of the carbon molded structure according to the present invention.

Figure 3 is a cross-sectional view showing the ossuary of the carbon molded structure according to the present invention.

[Description of Symbols for Main Parts of Drawing]

100. Ossuary container 110. Ossuary container

112. Ash bone entrance 114. Interior space

116. Sealing step 120. Inner lid

122. Packing groove 124. Sealing packing

130. Top cover 132. Bottom border

140. Yeongjung photo seating part

150. Youngjung Photo Fixation 10. Ashes

12. Youngjung Photo

The present invention configured to achieve the above object is as follows. That is, the ossuary box of the carbon molded structure according to the present invention has an internal space for storing the ashes in the state where the ashes inlet is formed on the upper side, but there is a certain size of the ossuary container in which a closed step is formed at the outer periphery of the ashes inlet. ; Youngjeong photograph seating portion is formed in the groove shape of a certain size on one side of the outer circumference of the ossuary container to allow the seating of the still life picture of the ashes powder; A permanent picture fixing piece which is formed in a size related to the permanent picture mounting part and is bonded to the permanent picture mounting part through the front surface of the permanent picture but is bonded or hard-fitted but made of a transparent material; An inner lid formed in a shape related to the ashes inlet of the ossuary container to open and close the ashes inlet, wherein a packing groove is formed at an outer circumference of the inner diameter surface of the ashes inlet; Sealing packing to be installed in the packing groove of the inner lid to close the inner lid to the ashes inlet to close the inner diameter surface of the ashes inlet to maintain the confidentiality of the inner space; And an outer lid that seals the inside through close contact with the sealing step of the ossuary container and opens and closes the entire upper portion of the ovarian container.

At this time, the crypt bone container, the inner lid and the outer lid of the above-described configuration is 94 to 96% by weight of the charcoal mixture of fine powder charcoal, volatiles and ash in a ratio of 98.23: 0.88: 0.89% by weight and 4-6% by weight In the form of a mixture in each state of the first heating for 600 to 800 hours three times under the temperature conditions of 1150 ~ 1250 ℃, and the primary heating molding for 90 to 110 hours from room temperature to 3000 ℃ After slowly densifying the tissue by secondary heating, a carbon coating layer is formed on the surface of the secondary heating molding to form a carbon molded body produced by tertiary heating for 30 to 40 minutes under a temperature condition of 380 to 420 ° C.

In the above-described configuration, the carbon coating layer of the carbon molded urn box 100 may be formed of a coating layer formed by spray coating a carbon coating liquid mixed with 40 to 50% by weight of fine powder charcoal and 50 to 60% by weight of Teflon fluorine resin solution. .

Hereinafter, the ossuary of the carbon molded structure according to the preferred embodiment of the present invention will be described in detail.

1 is an exploded perspective view showing the cavities of the carbon molding according to the present invention, Figure 2 is a front view showing the cavities of the carbon molding according to the present invention, Figure 3 is a coupling showing the cavities of the carbon molding according to the present invention It is a cross section.

As shown in FIGS. 1 to 3, the ossuary box 100 of the carbon molded structure according to the present invention has far-infrared radiation function, anion emission function, humidity control function and anti-corruption function, which are the functions of the inorganic components and charcoal included in the charcoal. By preventing the condensation (humidity) phenomenon inside the ossuary box to prevent the corruption of the ashes powder for the long-term storage of the ashes powder (10).

Looking at the structure of the ossuary 100 according to the present invention for achieving the purpose as described above are as follows. That is, the ossuary box 100 of the carbon molded structure according to the present invention is the ossuary container 110, the ashes inlet 112, which can store the ashes powder 10 in the internal space 114 through the ashes inlet 112 of the upper side. Sealing packing 124 and ossuary to be installed on one side outer circumferential surface of the inner lid 120, the inner lid 120 to close and close) to be in close contact with the inner diameter surface of the bone inlet 112 to maintain the airtightness of the inner space 114 It consists of a configuration of the outer lid 130 to open and close the entire upper portion of the container (110).

The ossuary box 100 configured as described above has the ashes inlet 120 into the inner lid 120 in a state in which the ashes 10 are put into the internal space 114 through the ashes inlet 112 of the ossuary container 110. Closing 112 to close the inner lid 120 and the sealing packing 124 to be made, through the outer lid 130 to close the entire upper side of the ossuary container 110 once again to seal the triple. Let's do it. At this time, the lower edge 132 of the outer lid 130 is in close contact with the state supported on the sealing step 116 of the ossuary vessel 110 to seal the interior space 114 of the ossuary vessel 110 in triple. do.

On the other hand, the present invention, in addition to the configuration of the sternum container 110, the inner lid 120 and the outer lid 130 as described above so that can be attached to the picture of life 12 of the remains of the ashes (10) It is further provided for the configuration, such that the structure of the attachment 12 is a size associated with the zero seating portion 140 and the zero seating portion 140 is formed in a groove shape on one side of the ossuary container 110. It is made of a fixed picture piece 150 is formed by being bonded through bonding or interference fit.

As described above, the attachment structure of the permanent photograph 12 is formed by forming the permanent photograph 12 into a size related to the permanent photograph seating unit 140, and then seating the permanent photograph. The permanent photograph 12 is fixed by coupling to the permanent photograph mounting portion 140 through the front of the permanent photograph 12 seated on the 140.

Combination of the above-mentioned still-image fixing piece 150 may be bonded to the zero-shaped seating part 140 by bonding an adhesive (not shown) to the rear edge of the still-photographic fixing piece 150, and also to fix it. The size of the photographic fixing piece 150 may be fixed to the size related to the photographic seating unit 140 through the interference fit. At this time, the zero picture fixing piece 150 is made of a transparent material such as acrylic plate so that the zero picture 12 can be seen from the front.

In addition, when the separation of the permanent photo fixing piece 150 from the permanent photo fixing part 140 is inserted into a side such as a pin or an auger, the permanent photo fixing piece 150 is separated. The fixing piece separating groove 142 is formed to allow.

When describing the structure of the ossuary box 100 of the present invention in more detail. First, the ossuary container 110 is for storing the ashes powder, the ossuary container 110 is inside the bones 10 can be stored therein in a state in which the ashes inlet 112 of a predetermined size is formed on the upper side. The space 114 is formed. At this time, since the outer periphery diameter of the ashes inlet 112 is made smaller than the outer periphery of the ossuary container 110, the upper surface between the outer periphery of the ossuary container 110 and the outer periphery of the ashes inlet 112 is flat. A sealing step 116 is formed.

When the outer step 130 for the sealing step 116 is covered with the outer lid 130 to the upper side of the ossuary container 110, the lower edge 132 of the outer lid 130 is in close contact with the inner space of the ossuary container 110 It serves to seal 114 in triple.

The inner lid 120 is for opening and closing the ashes inlet 112 of the ossuary container 110, the inner lid 120 is formed in relation to the shape of the top surface and the inner diameter of the ashes inlet 112. That is, as shown in Figure 3, the inner lid 120 is formed in the shape of the cross-section "T" of the interior space of the sternum container 110 by being in close contact with the upper surface as well as the inner diameter of the bone inlet 112. ) Will be sealed.

Meanwhile, a packing groove 122 is formed at an outer circumference adjacent to the inner diameter surface of the ash opening 112 of the inner lid 120, and a sealing packing 124 is fastened to the packing groove 122 so that the inner lid ( When the inner space 114 is closed by fastening the 120 to the ashes inlet 112, the inner space 114 is closed by the inner lid 120 and the sealing packing 124. Therefore, the outside air and the interior space 114 is completely blocked.

Outer lid 130 is for opening and closing the entire upper part of the ossuary container 110, the inside of the outer lid 130 is the ashes inlet 112 and the sealing step 116, which is the upper side of the ossuary container 110. It is formed in relation to this form.

When covering the outer lid 130 configured as described above on the upper side of the ossuary container 110, the bottom edge 132 of the outer lid 130 is closed stepped formed in the outer periphery of the ash opening 112 116 is in close contact with the surface, the inner surface of the outer lid 130 is adjacent to the outer periphery of the bone inlet 112 and triples the inner space 114 of the ossuary container 110 together with the inner lid 120. It will be sealed.

Youngjung picture seating portion 140 is for seating the youngjung picture 12, which is a living life of the bone ash (10), this youngjung picture seating portion 140 of a certain size on the outer peripheral surface of the ossuary container (110) It is formed in the shape of a groove.

The fixed picture fixing piece 150 is for fixing the fixed picture 12 seated on the fixed picture fixing part 140. The fixed picture fixing piece 150 has a size related to the fixed picture fixing part 140. It is formed and coupled to the seating part 140 through the front of the permanent picture (12).

On the other hand, the fixed picture fixing piece 150 formed as described above is fixed to the fixed picture mounting portion 140 through the adhesion or interference fit to the fixed picture mounting portion 140. At this time, the photographic fixing piece 150 is made of a material such as a transparent acrylic plate so that the photographic image 12 can be seen from the front.

As described above, the ossuary 100 configured as described above may be embodied in various forms such as egg-shaped (elliptical), spherical, cylindrical, cuboid, polygonal, lotus, Maria, and supper. will be.

On the other hand, the manufacturing method of the carbon box structure of the carcass 100 according to the present invention configured as described above is a charcoal mixture 94 ~ 96 weight by mixing the fine powder of charcoal, volatiles and ash in a ratio of 98.23: 0.88: 0.89% by weight % And 4-6% by weight of wood vinegar, the process of shaping the charcoal mixture in the form of the ossuary container 110, the inner lid 120 and the outer lid 130, the respective moldings at a temperature of 1150 ~ 1250 ℃ Under the conditions, the first heating process (primary roasting process), which is first roasted for 600 to 800 hours in three times, and the first heating molding (first roasting molding) baked through the first heating process, is carried out for 90 to 110 hours. 40-50% by weight of fine powdery charcoal on the surface of the secondary heating process (the chaebol roasting molding) baked through the secondary heating process to gradually compact the structure of the molding by heating gradually. Teflon Fluoropolymer 50 ~ 60 Urticaria of the carbon molded structure through a process of forming a carbon coating layer (not shown) coated by mixing the amount of the amount and tertiary heating for 30 to 40 minutes under a temperature condition of 380 to 420 ° C. 100 is prepared. At this time, in the manufacturing process of the prepared carbon molded box crypt box 100, the cooling after the first, second and third heating is cooled through natural cooling at room temperature.

In the manufacturing process of the carbon molded urn box 100 as described above, because the carbon coating layer is a mixture of fine powder of charcoal and Teflon fluororesin and applied to the surface of the molding, it may also be called Teflon coating in another sense. have. This Teflon Coating is a coating of Teflon {Teflon (fluorocarbon resin): a fluorine carbide-based trademark of Dupont, USA, which has unique physical and chemical properties that other polymer compounds do not have.} Non-adhesive through pre-treatment process, drying, heating and firing process using spray coating and electrostatic powder on existing materials such as iron, stainless steel, aluminum, copper, glass, rubber and ceramic plastic It means excellent fluorine resin coating to obtain Teflon's unique characteristics such as chemical resistance, oil resistance, heat resistance, insulation, and abrasion resistance.

In addition, the above-described Teflon coating is known to have excellent non-tackiness, low friction coefficient, oil resistance, heat resistance, electrical properties, low temperature durability and chemical resistance. In particular, the Teflon coating is excellent in non-tackiness that almost all materials do not stick to and non-tackiness of water or oil so that moisture can be prevented from sticking.

The theoretical background of the main material of the charcoal constituting the ossuary box 100 of the carbon molding structure according to the present invention as described above, first, the charcoal is a carbon material has a special property, so that its use for household, agriculture, forestry, fishing, light industry, etc. Varies. The main components of charcoal are carbon (C ¹⁴ ) and minerals. When burning wood absorbing Ca, K, Na, Mg, etc. from the soil, organic acids and moisture are evaporated, leaving only carbon and minerals. It is estimated that far infrared rays are emitted by trace minerals, such as germanium (Ge) component absorbed from soil among these components.

The above-mentioned charcoal includes physical functions based on the structure and structure of the charcoal, physical and chemical functions of the minerals and the acidity of the charcoal, active points of the inner surface, and the function of microorganisms to be colored on the surface and It has the function of purifying air and water by mutual correlation.

In addition, it is known that charcoal has a strong adsorption force for adsorbing molecules of gas and liquid. The mechanism of action of charcoal can be explained by adsorption force. Charcoal is composed of a lot of very fine pores formed in the manufacturing process and has a large surface area. It provides a binding site for adsorption and binding, so the char will have adsorption power. In other words, the charac- ter of the internal surface of the char is that it attracts any molecules that can fill the micropores. This is the adsorption power of charcoal. At this time, since the force between molecules is relatively weak, the adsorbed molecules are separated when the char is applied from the outside (for example, exposed to pure water). This allows char to be used for a variety of purposes because it only has adsorption without changing itself or changing other substances.

On the other hand, the efficacy of the charcoal having the function as described above is far infrared radiation function, charcoal is far superior to the emissivity and radiation energy of far infrared rays than any other material. In addition, with the function of releasing anions, the anions function to neutralize the cations in the surroundings that have increased rapidly due to various contaminations. Thus, the negative ions released from the char can purify the air. However, the charcoal box 100 of the carbon molded structure of the present invention has a slight release of negative ions than the original anion emission of char.

In addition, charcoal can absorb electromagnetic waves harmful to the human body from various electrical appliances due to its conductivity. Charcoal has hundreds of thousands of pores per gram, so it absorbs when there is a lot of moisture and emits it when dried. . The humidity control function of the charcoal can be expected to insect repellent, antibacterial effect, mold growth inhibition and deodorizing effect.

Moreover, the function of charcoal includes anti-corruption and deodorization functions. Such charcoal is widely used to purify drinking water and many other products, recover volatiles, adsorb odorous substances or colored substances, It is very effective in deodorization and antiseptic to adsorb gas and odor. This effect is incredibly charcoal composed of a myriad of pores, hardly to believe the surface area (measuring the internal surface of the pores formed on the charcoal has a cross-sectional area of about 200 ~ 400m ² per 1g of charcoal, if 1g of charcoal to break very empty all The total surface area of the particles is about 1,200 m ² ), which is a very good structure for microorganisms. In fact, the pores of charcoal are inhabited by beneficial microorganisms such as bacteria and actinomycetes, and these microorganisms decompose and remove harmful bacteria, gases and odors adsorbed on the surface of charcoal through continuous decomposition.

In particular, the carbage box 100 of the carbon molded structure mainly composed of charcoal of the present invention can be said to be a product having an excellent effect of far infrared rays. Such far infrared rays refer to infrared rays having a wavelength of 30 to 1,000 microns. When absorbed into the body, it penetrates into the subcutaneous depth 80 times deeper than normal heat and radiates into the water and protein molecules that make up the cells in the human body, and activates the tissue by vibrating the cells about 2,000 times a minute. The activation process of these tissues not only generates heat energy, but also has an effect of naturally discharging waste products, which are harmful substances of cells in the human body. Thus, the vital activity of the human body becomes more active.

In addition to the effects described above, far infrared rays influence the cells, which are the most basic tissues of the human body, to promote blood circulation and enhance the body's self-defense ability, as well as to promote health recovery, to relieve pain, remove heavy metals in the body, and promote sweating. It is known to have effects such as sound sleep, deodorizing effect, antibacterial effect, insect repellent effect, dehumidification effect, mold growth prevention, dehumidification and air purification.

Therefore, the urine box 100 of the carbon molded structure according to the present invention has far-infrared radiation function, anion release function, humidity control function, anti-corruption and deodorization function, which is the main function of charcoal, and thus the urine box of the carbon molded product structure of the present invention. (150) is a charcoal such as fungi by preventing the condensation (humidity) phenomenon that can occur inside the ossuary container 110 through the far infrared radiation function, anion emission function, humidity control function, anti-corruption and deodorization function that charcoal has It will prevent the breeding.

Therefore, the ossuary box 100 of the carbon molding structure according to the present invention is the ash bone powder stored inside the ossuary container 110 through the far-infrared radiation function, anion emission function, humidity control function, anti-corruption and deodorization function which is the main function of charcoal ( 10) Long-term storage is possible by preventing corruption.

The present invention is not limited to the above-described embodiments and can be carried out in various modifications within the range allowed by the technical idea of the present invention.

As described above, according to the present invention, the ossuary is made of a carbon molded structure composed mainly of fine powdery charcoal, so that the inorganic components contained in the charcoal and the far-infrared radiation function, anion release function, humidity control function and anti-corruption function of the charcoal are included. Through the condensation (moisture) phenomenon inside the ossuary has the effect of preventing the corruption of the ashes.

In addition, the present invention is to prevent the condensation (humidity) of the ashes in the ash box through the inorganic components and the charcoal function of far-infrared radiation function, anion release function, humidity control function and anti-corruption function of the carbon box structure. By preventing rot has the effect of long-term preservation of bone ash.

Claims (2)

An oscillation container having a predetermined size formed on the outer circumference of the ash entrance, wherein an internal space for storing the ashes therein is formed in the state where the ash entrance is formed; Youngjeong photograph seating portion is formed on the outer circumferential surface of the ossuary container has a certain size of the groove shape to allow the youngjong photograph, which is the life of the ashes, to be seated; A permanent picture fixing piece formed of a size related to the permanent picture seating part and coupled to the permanent picture seating part through adhesion or interference fit through a front surface of the permanent picture but made of a transparent material; An inner lid formed in a shape related to the ashes inlet of the ossuary container to open and close the ashes inlet but having a packing groove formed on an outer circumference of the inner diameter surface of the ashes inlet; Sealing packing to be seated in the packing groove of the inner lid is in close contact with the inner diameter surface of the ashes inlet when the inner lid is fastened to the ashes inlet to maintain the airtightness of the inner space; And It is made of an outer lid that seals the inside through close contact with the sealing step of the ossuary container and opens and closes the entire upper part of the ovarian container. The ossuary container, the inner lid and the outer lid are mixed with fine powder charcoal, volatile powder and ash at a ratio of 98.23: 0.88: 0.89% by weight of the mixture of 94 to 96% by weight and 4 to 6% by weight of the vinegar solution. In the state of forming in the form, the first heating for 600 to 800 hours three times under the temperature conditions of 1150 to 1250 ℃, the secondary heating is gradually heated for 90 to 110 hours from room temperature to 3000 ℃ After compacting the structure, the carbon molded body formed of a carbon molded product produced by the third heating for 30 to 40 minutes under a temperature condition of 380 ~ 420 ℃ by forming a carbon coating layer on the surface of the secondary heating molding Rescue of the structure. The method of claim 1, wherein the carbon coating layer is a coating layer formed by spray coating a carbon coating liquid mixed with 40 to 50% by weight of fine powder charcoal and 50 to 60% by weight of Teflon fluorocarbon resin solution. Grill.