KR100445338B1 - equipment of manufacture crystalloid from the person's ashes - Google Patents

Abstract

The present invention relates to a mechanical device for producing crystals from bone meal by finely pulverizing the remains of the body after cremating the body, and then heating them again at a high temperature. The present invention comprises a heating part and a raw material supply part. It has a heating container for dissolving bone meal, and has a heating nozzle radiating flame on one side of the heating container, and a rotary fine rod for finely separating the melted melt into small pieces and a blowing fan and a blower pipe for cooling below the heating container. And a vibrating conveying plate for conveying it, and forming a rounded melt liquid into small pieces, and having a feed shaft for transferring bone powder on a support plate which is moved left and right, and a hopper and a screw shaft of the conveying pipe for storing bone powder. The rotating motor is installed.

Description

Equipment for making crystals from remains after cremation {equipment of manufacture crystalloid from the person's ashes}

The present invention relates to a mechanism for cremating a dead body and collecting the remaining ashes, then heating and melting them again at a high temperature and cooling them to crystallization.

For human beings, death has the same significance as birth, and the body treatment of the dead is done according to the styles and customs determined by each nation or religion.

The funeral rituals in Korea are mostly preferred to bury the dead in the cemetery due to traditional Confucian or Feng Shui thoughts.

Due to the problems caused by the increase of the cemetery every year, the government or social organizations are recommended to cremise the body, put it in a container, and store it in the ossuary.

However, most citizens prefer the cemetery according to traditional funeral rituals, and the national sentiment is that they do not prefer to cremate their bodies and store them in the ossuary. In particular, when the body is cremated and the ashes are collected and placed in a container, and stored in the ossuary, the ossuary ashes have an unsightly shape, so even if they are close relatives, the ossuary ashes are reluctant over time. This caused more intense use of the cemetery than placing the ashes in the ossuary.

The present invention was conceived in view of the fact that it is reluctant to store the cremated ashes in the ossuary, and the ashes of the cremated ashes are heated again at a high temperature to remove impurities in the bone powder and in a molten state. After cooling it to a smaller size, it is reduced to a volume of 1 / 3-1 / 5 of the original volume of the ashes, and recrystallized into jade-colored crystals. There will be no.

In particular, jade-colored crystals are beautiful in appearance when stored in glass containers, so that they can be stored in each home without the need for cumbersome place in the ossuary.

The present invention is to provide a mechanism for producing crystals from the ashes generated after cremation.

In the present invention, after the body is cremated, the remaining bone is heated again at a high temperature to produce crystals. In order to heat the bone powder to be in a molten state, a high temperature of at least 1600-2000 ° C. must be maintained for a predetermined time.

Therefore, the container heated with bone meal must endure at a high temperature of at least 2000 ° and supply a constant high temperature. For this purpose, the heating container containing bone powder is made of ceramic material or alumina material, and is provided with a heating nozzle which continuously supplies a flame of at least 1800 ° C. It has a transfer plate, a blower fan, and a blower tube for movement, and it is possible to produce crystals from bone meal so that all processes are automatically performed from bone meal administration to heating, cooling, and crystal formation.

1-Schematic cross section of the present invention.

2-A schematic cross-sectional view taken along line A-A of FIG.

Figure 3-Schematic cross-sectional view of the A-A line use state of Figure

The present invention is largely composed of a heating unit (A) and the raw material supply unit (B), the heating unit (A) has a heating vessel (10) in the center, the bone container administration port (11) and flame in the heating vessel (10) It has an inlet 12, the heating vessel 10 is attached to the rotating shaft 13 for forward and reverse rotation, the forward and reverse rotation actuator 15 is attached to the end of the rotating shaft 13, the heating In front of the flame inlet 12 of the vessel 10 has a heating nozzle 21, the heating nozzle support 22 of the heating nozzle 21 is connected to the nozzle moving mechanism for moving up, down, left and right, and the heating vessel Directly below (10) has a rotating fine rod 25, a vibration transfer plate 26, a blower fan 27 and a blower tube 28, each of which is a rod, the support plate which is movable left and right on the raw material supply (B) ( 31 to feed the raw material to the transfer pipe 32 having the screw shaft 33 on the inside and the motor 34 and the transfer pipe 32 to operate the screw shaft 33. Flops 35 a, and has the support plate 31, the slider 36 attached to the lower end is a so sapchi to the stationary plate 37, a plurality of slider shaft 38 of the right and left ends fixed to the.

In the above, the heating container 10 is made of a ceramic material or alumina, and the heating nozzle 21 is a water supply port 21-1, a water outlet 21-2 and a mixed gas supply pipe 21 for water cooling. -3), the transfer plate 26 is composed of a curved corrugated plate, the forward and reverse rotation actuator (15) attached to the other end to the rotating shaft (13) of the heating vessel (10) is an automatic operation mechanism for compressed air or A forward and reverse rotation mechanism consisting of a rack gear and a pinion gear operated by hydraulic pressure or a general motor having a deceleration device is generally used. In order to operate manually, a handle having a gearbox is attached to the heating container 10. 180 ° forward or reverse rotation.

In addition, the heating nozzle 21 positioned on one side of the heating vessel 10 may arbitrarily adjust the angle with the heating nozzle support 22 by the lever 22-1, and the lower end of the heating nozzle support 22 may be left or right. It is possible to arbitrarily adjust the height by the cylinder operating mechanism moving back and forth and the gear device moving up and down.

In the drawing, reference numeral 51 denotes an exhaust port, 52 denotes a partition wall between the heating part A and the raw material supply port B, and 53 denotes a moving hole of the transfer pipe 32.

The present invention having such a structure will be described in more detail and at the same time, as described below.

The finely divided bone powder is administered to the hopper 35 and the slider 36 fixed to the support plate 31 is operated to move the feed pipe 32 together with the support plate 31 to the inside of the heating part A. After placing the outlet of the transfer pipe 32 to the upper portion of the heating vessel 10, by operating the motor 34 in the rear end of the transfer pipe 32 to rotate the screw 33 inside the transfer pipe 32 to the hopper ( After administering the bone powder in 35 into the heating container 10 through the bone powder injection port 11, the slider 36 of the support plate 31 is reversed to support the support plate 31 and the transfer pipe 32 disposed thereon. ) And the hopper 35 are returned to the raw material supply port (B). The left and right movement of the slider 36 uses a liner plate actuating mechanism operated by hydraulic pressure or pneumatic pressure, or moves the slider left and right by a cylinder having a reciprocating piston.

At this time, the bone powder was heated at a low temperature of about 500 ° C. for the first 5 minutes to form a film on the surface of the bone powder, and then heated at a temperature of about 1000 ° C. for 10 minutes to form the bone powder as a lump, and then about 1600 When heated to a temperature of -1800 ℃ for about 20 minutes, impurities contained in the bone powder are burned and removed, and only inorganic matters remain to be melted.

After dissolving the bone powder in this way, the forward and reverse rotation mechanism 15 attached to the other side of the rotary shaft 13 connected integrally with the heating vessel 10 is operated to rotate the heating vessel 10 by 180 °. The bone powder inlet 11 that is located at the downward direction, the molten bone melt dissolved through the bone powder inlet 11 is dropped.

As such, the bone lysate falling from the heating vessel 10 is separated into small pieces by the rotating triangular or square column-shaped rotary shaft 25 to be dropped into the vibration conveying plate 26, and the vibration conveying plate. (26) The bone lysate is cooled and recrystallized into spherical grains of about 2-7 mm in diameter while being cooled by the wind supplied through the rear blower tube 28 and discharged through the vibration transfer plate 26. You lose.

The present invention relates to a mechanism for making up the body and heating the remaining bone powder again at a high temperature to completely burn the organic matter in the bone powder and at the same time to cool the minerals in the molten bone powder to recrystallize it into small grains.

In the present invention, the remaining bone meal after making up the body is heated again at a high temperature to completely remove and remove the organic matter in the bone meal, and when the molten inorganic material is cooled and re-determined into small grains, it is recrystallized into jade grains and then after conventional makeup It has a completely different appearance from the ashes of ash, and as before, the worrisome preconceived notions about the ashes are removed.

In this way, the ashes are melted to make a recrystallized material, and the remaining ashes after cremation are finely pulverized into powder, and when heated again at a high temperature of 1700-1800 ° C., the bone powder is dissolved and melted.

Therefore, it is preferable that the heating container in which bone powder is added and dissolved for a predetermined time is made of a ceramic material or an alumina material that can withstand a high temperature of 2000 ° C. or more for a long time.

In addition, in order to make a flame at a high temperature of 2000 ° C. or higher, an appropriate ratio of a mixture gas of LPG gas and air (or oxygen) is required. In particular, the flame supplied from the heating nozzle 21 must be very strong in order to heat the bone powder in the heating container in a molten state in a short time. Therefore, in order to prevent the heating nozzle 21 from being damaged by the strong flame, in the present invention, the heating nozzle is constituted by a double pipe, and the gas supply pipe 21-3 is a mixture gas of LPG gas and air at the inner center. The outer tube is supplied with water through the water supply port 21-1 and the water discharge port 21-2 to prevent the heating nozzle 21 from being damaged by heat.

In addition, the heating nozzle 21 can be adjusted at any angle with the heating nozzle support 23 for supporting and fixing the heating nozzle 21, the heating nozzle support 23 is moved to the front, rear, left and right, within a predetermined range by heating the nozzle ( It is possible to arbitrarily adjust the direction of the flame generated from the tip of 21).

In addition, a partition wall 52 is provided between the heating part A and the raw material supply part B, and a transfer hole 53 is formed at the upper end of the partition wall, and the transfer pipe of the raw material supply part B is formed through the transfer hole 53. 32 is free to move to the heating portion A.

Therefore, after discharging the outlet of the transfer tube 3 directly above the heating vessel 10, and after administering the bone powder into the heating vessel 10, the transfer tube 32 is retreated to the raw material supply (B) to re- Since the position is located, the heat generated when the heating vessel 10 is heated by the heating nozzle 21 is not acting other than the heating vessel 10.

In addition, heat and gas generated from the heating nozzle are discharged out through the upper exhaust port 51.

The present invention relates to a mechanism for making crystals from bone flour by crushing the remains remaining after cremating the body and heating fine bone powder again at a high temperature.

When the bone meal is heated and melted, it is divided into small pieces and cooled to recrystallize into shiny turquoise or jade granules.

Therefore, in order to heat and melt the bone powder, it is necessary to have a heating container capable of withstanding a high temperature of 2000 ° C., and all operating means are preferably operated automatically since the high temperature must be maintained for a certain time.

In order to satisfy such conditions, the present invention is largely divided into a heating part (A) and a raw material inlet (B), and the heating part (A) has a heating container 10 inside the heating container, but the administration of bone powder and molten bone powder It has a bone injection port (11) for discharging it, and has a flame inlet (12) is supplied with flame on the side, the heating vessel (10) is 180 ° forward, rotating shaft (13) capable of reverse rotation and rotation operation The instrument 15 is integrally formed to facilitate administration of bone meal and discharge of the molten melt.

In particular, the falling melt is dispersed by the triangular or square column-shaped rotating cutting rods 28 and the dispersed one is spherical or elliptical in size while traveling through the vibrating conveying plate 26 (diameter about 2- It is recrystallized from 7mm) turquoise or jade colored crystals, and its color has the same color and luster as the saree extracted from the bones of old monks who have been performing for a long time.

Therefore, the recrystallization thus disappears the conventional preconceived notion of ashes, and when it is stored in a transparent glass box does not need to be placed in the ossuary.

As such, the present invention has a smaller volume of 1 / 3-1 / 5 than the ashes left after the conventional cremation, and is recrystallized as jade crystals, so that the deceased's bereaved family can keep it separately so that they do not use the ossuary. You can also

Therefore, it is possible to improve the conventional cremation culture in which the ashes are stored in the ossuary, and in particular, to provide a good opportunity to guide cremation to the funeral procedure of performing the conventional burial of the dead in the cemetery. It is a very useful invention that has the advantage of preventing the increase of the land and covering the land with the cemetery and preventing the land from being encroached into the cemetery.

Claims (3)

Consists of a heating unit (A) and a raw material supply unit (B), the heating unit (A) has a heating vessel (10) in the center, the bone container administration port (11) and flame inlet (12) in the heating container (10) The heating vessel 10 is attached to the rotary shaft 13 for forward and reverse rotation thereof, the forward and reverse rotation actuator 15 is attached to the end of the rotary shaft 13, the heating vessel 10 In front of the flame inlet 12 of the heating nozzle 21, the heating nozzle support 22 of the heating nozzle 21 is connected to the nozzle moving mechanism for moving up, down, left and right, and the heating vessel 10 of the Directly below has a rotating fine rod 25, a vibrating conveying plate 26, a blowing fan 27, and a blowing tube 28, each of which is made of an angled rod, and on the support plate 31 which is movable left and right in the raw material supply part B. Has a feed pipe 32 having a screw shaft 33, a motor 34 for operating the screw shaft 33, and a hopper 35 for supplying raw materials to the feed tube 32. , Apparatus for making the crystals from the remaining ashes the support plate 31, the slider 36 is attached to the bottom, after make-up, it characterized in that the so sapchi to the stationary plate 37, a plurality of slider shaft 38 of the right and left ends fixed to the. The apparatus of claim 1, wherein the heating vessel is made of ceramic material or alumina material. The apparatus of claim 1, wherein the heating nozzle (1) has a water supply port (21-1) and a water discharge port (21-2) for cooling water.