KR101075865B1 - The Crucible Furnace for Powdered-bones and the Apparatus for Melting Crystallization Powedered-bones using the Same - Google Patents

Abstract

The present invention relates to a bone powder melting crucible for heating and liquefying bone powder remaining after cremation of a corpse and a bone powder melting crystallization apparatus for making molten bone powder into crystals.

In the bone powder melting crucible, an outlet 11b through which the bone powder introduced into the interior through the upper opening 11a is melted and discharged is formed at the bottom, and the lower portion is formed in a funnel shape, and has a cylindrical shape made of a heat-resistant ceramic material. Crucible 11; An outer crucible 12 made of graphite material in which the inner crucible 11 is accommodated in a state in which the inner circumferential surface and the outer circumferential surface of the inner crucible 11 are spaced to some extent; The mounting ring 13 is integrally attached to the upper side of the inner crucible 11 and is mounted on the upper surface of the outer crucible 12 to support the bottom surface of the inner crucible 11 to be positioned higher than the bottom surface of the outer crucible 12. and; The heater coil 14 for heating is provided therein, the outer crucible 12 is accommodated in a state in which the inner circumferential surface and the outer circumferential surface of the outer crucible 12 are spaced to some extent, and the inner surface is provided on the bottom surface that supports the outer crucible 12. A heating furnace 15 having an outlet 15 'formed at the outlet 11b of the crucible 11; A lid 16 positioned at an upper portion of the heating furnace 15 to seal an upper surface of the heating furnace 15; A gas discharge pipe 17 installed perpendicular to the lid 16 to discharge gas generated from the inner crucible 11; And a nitrogen supply pipe 18 installed at the lid 16 to supply nitrogen gas to the inner crucible 11.

The bone powder melting crystallization apparatus includes a cold conveying member 20 installed at the crucible melting furnace crucible 10 and a lower portion thereof to cool and melt the molten liquid falling from the bone powder melting crucible furnace 10 to be transferred to a collecting container. And, the cooling transfer member 20, a plurality of rounds are installed inclined at a predetermined angle and arranged in a zigzag form continuously and a plurality of rounds are continuously installed in the width direction on the upper surface of the cooling tracks 21 Bar 22, a hole 23 'through which the bone powder melt passes, and a case 23 on which the cooling track 21 is fixed, and an inclined portion below the end of the lowermost cooling track, the collection container 30 It is characterized in that it comprises a discharge guide plate 24 for discharging the crystal to the) and a vibration generator 25 is installed in the lower portion of the case 23 to generate vibration in the case.

Bone meal, ashes, crystals, ferns, vibrations, cooling, crucibles, furnaces, melting, calcium phosphate

Description

Crucible Furnace for Melting Bone Powder and Melt Crystallization Apparatus Using The Same {The Crucible Furnace for Powdered-bones and the Apparatus for Melting Crystallization Powedered-bones using the Same}

The present invention relates to a bone powder melting crucible for heating and liquefying bone powder remaining after cremation of a corpse, and a bone powder melting crystallization apparatus for making molten bone powder as crystals, and in particular, it is possible to melt bone powder without adding an additional additive. The present invention relates to a crucible for melting bone powder and to a melted molten crystallization apparatus using the same, which enable high temperature melting to melt bone powder in a short time to form a crystal.

In general, the funeral methods for dealing with bodies when a person dies vary according to the culture, climate and customs of the region. Representatives include the facilitation of birds to peck the birds, a windpan that places the body where the wind blows so that the body can be dismantled, a chief that drowns the body in the water, and a cremation that burns the body.火 매장, burial buried in the ground, etc. Particularly in countries influenced by Confucian culture, such as Korea and China, they prefer the burial method under the influence of traditional Confucian or Feng Shui thoughts. There is a custom.

However, the traditional burial ritual of burial method is a national problem that the cemetery has eaten up a large part of the country and reduces the space available to descendants, and it is difficult for the descendants living in various trends in the busy modern society to manage the cemetery. It is causing family problems. In addition, there are a number of social problems, such as a rapid increase in population movement for holy days, such as holidays, causing traffic jams.

Recently, the use of the cemetery is regulated by the law, such as setting the duration of the cemetery or limiting the size of the cemetery, and it is encouraging the cremation to prevent various dislocations caused by the cemetery. It's turning to good.

On the other hand, the general cremation culture is a form in which the remains left after cremating the body are placed in a certain container, that is, in the ossuary. However, after the cremation of the body, it is not easy to collect and store the ashes, and since the ashes themselves tend to harm the aesthetics, the popularization of the cremation culture has been delayed, such as avoiding the installation of crematory or ossuary in each region.

In addition, even when the ashes are stored in the ossuary sugar, there is a problem that long-term storage is difficult because the ashes are decayed due to moisture or the like and cause various odors to invade and damage the ashes. The ashes usually contain powdered ashes, that is, bone meal. Due to the nature of the ashes, which strongly absorb moisture from the surroundings, the ashes deteriorate and decay when stored for a long time, and various pests invade due to neglect of management. Can be damaged.

Recently, in order to solve the problem of the storage of the ashes, a method for storing the ashes for a long time by heating the ashes and forming them into crystals has been developed, and is also known as Korean Patent Nos. 154428 and 40407.

Patent No. 154428 discloses a method in which bone powder is heated to 1700 ° C. to be melted, and then poured into water at room temperature and cooled to obtain crystals. However, in this method, since the bone powder melt is cooled in water at room temperature, the crystals are not spherical but have a rod-like shape, so that they often have a sharp and sharp tip. It becomes weak and easily broken.

In addition, Patent No. 407145 heats bone powder at low temperature to form a film on the surface of bone powder, and then aggregates the bone powder into lumps at medium temperature (900-1000 ° C.), and melts and melts the aggregated bone powder at high temperature (1700-2000 ° C.). Disclosed is a method of forming a crystalline liquid bone powder into a spherical shape or cooling with a new phase crystal. However, this method requires two heat treatments, the manufacturing process is complicated, and there is a problem that only standardized crystalline grains can be obtained.

On the other hand, the known bone powder melt crystallizer is a crucible furnace (1) for heating and melting bone powder as shown in Figure 1, and a cooling track for transporting while cooling the bone powder melt in the lower portion of the crucible furnace (1) 2), a collection vessel (3) for collecting the cooled and crystallized bone powder crystals while being transported by the cooling track (2), a cooling device (4) for cooling the bone powder melt, and the cooling track (2) And a plurality of blowers (5) for blowing cold air generated in the cooling device (4) to a plurality of transporting bone powder melts for blowing cold air and releasing hot gas to the outside of the device. The control panel 6 for controlling is provided.

The conventional bone powder melt crystallization apparatus melts bone powder in a crucible furnace and transfers the melted bone powder to a cooling track, which is cooled to make crystals and collected in a collecting container.

Bone powder, glass, and other minerals are introduced into the crucible furnace 1, and the bone powder melts when heated for a predetermined time while maintaining the temperature inside the crucible furnace 1 at approximately 1700 ° C., and this melted bone powder is melted into the crucible furnace ( It falls to the cooling track (2) located in the lower part of 1). The dropped bone meal melt is gradually transported along the inclined cooling track 2, and at the same time, the cold air generated in the cooling device 4 is blown by the blower 5. Thus, the bone meal melt being transferred is crystallized while gradually cooling from the outside. After cooling to the inside and completely solidified crystals are collected in the collecting container (3) is completed all the process of crystallizing the bone meal.

However, the conventional bone powder melt crystallization apparatus, because it melts the bone powder at a temperature of 1700 ℃ takes a long time to melt the bone powder, due to the glass or other minerals introduced into the crucible furnace for melting the bone powder and Similar transparent or translucent crystals can be obtained, but there is a problem in that the color of bone powder itself can not appear.

The present invention has been made in order to solve the above-mentioned conventional problems, and to enable the melting of bone flour quickly using high heat without adding glass or other minerals, as well as the crucible for melting the bone powder to appear the color of the bone powder itself and It is an object of the present invention to provide a melt melt crystallization apparatus using the same.

In addition, an object of the present invention is to provide a bone melting melting crucible and a bone powder melting crystallization apparatus using the same, by which a high temperature of about 2300 ° C. can be quickly obtained by heating an internal crucible using a heat radiation method rather than a heat conduction method.

In addition, an object of the present invention is to provide a bone melting crucible and a bone powder melting crystallization apparatus using the same, so that the bone powder melt can not be attached to the device in the discharge process of the bone powder melt.

In addition, an object of the present invention is to provide a bone powder melt crystallization apparatus that allows the bone powder melt to be dispersed and spherically formed by dropping the bone powder melt or the hardened bone powder crystals while allowing the bone powder melt to vibrate up and down. .

Crucible for melting bone powder of the present invention for achieving the above object, the outlet of the bone powder injected into the interior through the upper opening is melted and discharged is formed in the bottom, the bottom portion is formed in a funnel shape that follows the outlet, heat-resistant A cylindrical inner crucible made of a ceramic material; An outer crucible of graphite material in which the inner crucible is accommodated in a state in which an inner circumferential surface and an outer circumferential surface of the inner crucible are spaced apart by a predetermined degree; An installation ring integrally attached to an upper end side of the inner crucible and seated on an upper surface of the outer crucible to support a bottom surface of the inner crucible higher than a bottom surface of the outer crucible; The heater coil for heating is provided therein, the outer crucible is accommodated in a state in which the inner circumferential surface and the outer circumferential surface of the outer crucible are spaced to a certain extent, and a discharge port is formed on the bottom surface supporting the outer crucible to the outlet of the inner crucible. A heating furnace; A lid positioned at an upper portion of the heating furnace to seal an upper surface of the heating furnace; A gas discharge pipe installed perpendicular to the lid to discharge gas generated from the inner crucible; And a nitrogen supply pipe installed on the lid to supply nitrogen gas to the inner crucible.

In addition, according to the crucible furnace for melting bone powder of the present invention, the heat-resistant ceramic forming the inner crucible includes aluminum oxide (Al ₂ O ₃ ), silicon dioxide (SiO ₂ ), and unavoidable impurities in magnesium oxide (MgO) as a main material. Characterized in that formed by mixing.

In addition, according to the crucible furnace for melting bone powder of the present invention, the outlet of the heating furnace is characterized in that the inner peripheral surface is formed in a wedge shape.

And the bone powder melting crystallization apparatus of the present invention, installed in the lower portion of the bone powder melting crucible and the bone powder melting crucible is cooled to crystallize the bone powder melt falling from the bone powder melting crucible furnace and then transferred to the collection vessel And a cooling transfer member, wherein the cooling transfer member comprises: a plurality of cooling tracks installed inclined at a predetermined angle and continuously arranged in a zigzag form, and a plurality of round bars continuously installed in a width direction on an upper surface of the cooling tracks; A hole through which the bone powder melt is formed and an upper portion of the case in which the cooling track is fixed, a discharge guide plate disposed to be inclined at the lower end of the lowermost cooling track to discharge crystals to the collection container, and a lower portion of the case. Installed is characterized in that it comprises a vibration generator for generating vibration in the case do.

In addition, according to the bone powder melt crystallization apparatus of the present invention, the vibration generator is characterized in that it is made of a vibrator installed on the lower portion of the case, a plurality of springs installed on the lower portion of the vibrator to elastically support the vibrator.

In addition, according to the bone powder melt crystallization apparatus of the present invention, the cooling track is bent inclined upwardly to form a drop induction portion, the uppermost cooling track of the cooling track is not provided with the round bar to a part downstream of the melt falling point It is formed by a flat plate, The drop guide piece which drops the melt liquid to the downstream side in which the round bar was provided in the edge part of a flat plate is characterized by the installation.

Crucibles for melting bone powder of the present invention are spaced apart between the inner crucible and the outer crucible, and between the outer crucible and the heating furnace, respectively, so as to rapidly heat the inner crucible to a high temperature of 2300 ° C. in a short time by heat radiation rather than conduction. There is an effect that can be melted.

In addition, according to the crucible furnace for melting bone powder of the present invention, as it supplies nitrogen to the internal crucible in which bone powder is melted, and also discharges exhaust gases such as water vapor generated in the melting process of bone powder to the outside, so discoloration of bone powder due to oxidation, etc. This has the effect of not occurring.

In addition, according to the crucible furnace for melting bone powder of the present invention, since the bone powder is heated and melted without a separate additive, there is an effect of obtaining a bone powder crystal having a color of the bone powder itself.

In addition, according to the crucible furnace for melting bone powder according to the present invention, the outlet inner circumferential surface of the heating furnace through which the bone powder melt is discharged is formed in a wedge-shaped cross section, so that the bone powder melt is not attached to the inner circumferential surface of the outlet, and thus all are discharged.

In the bone powder melt crystallization apparatus of the present invention, since the bone powder melt discharged from the crucible for melting bone powder passes through a round bar and is shaken by vibration, the bone powder melt can be spherically formed into small particles to obtain small and round crystals. It works.

In addition, according to the bone powder melt crystallization apparatus of the present invention, since the bone powder melt is dropped to the upper side of the round bar by the drop guide unit or the drop guide piece, there is an effect that the bone powder crystals or bone powder melt that are not completely hardened are spherically shaped by the surface tension. .

Hereinafter, with reference to the accompanying drawings illustrating a bone melting crucible of the present invention and a bone powder melting crystallization apparatus using the same.

Figure 2 is a schematic view showing a bone melting melting crucible furnace according to the invention, Figure 3 is a conceptual diagram of bonding to the melting powder crucible of the present invention, Figure 4 is a cooling of the main component of the bone powder melting crystallization apparatus according to the present invention A schematic diagram of a track is shown.

In the crucible for melting bone powder according to the present invention, the outlet 11b through which the bone powder introduced into the interior through the upper opening 11a is melted and discharged is formed at the bottom, and the lower portion is in a funnel shape connected to the outlet 11b. A cylindrical inner crucible 11 formed of a heat-resistant ceramic material; An outer crucible (12) of graphite material in which the inner crucible (11) is accommodated in a state in which an inner circumferential surface and an outer circumferential surface of the inner crucible (11) are spaced to some extent; It is integrally attached to the upper end side of the inner crucible 11 and is mounted on the upper surface of the outer crucible 12 to support the bottom of the inner crucible 11 to be positioned higher than the bottom of the outer crucible 12. A ring 13; A heater coil 14 for heating is provided therein, and the outer crucible 12 is accommodated in a state where an inner circumferential surface and an outer circumferential surface of the outer crucible 12 are spaced to some extent, and a bottom for supporting the outer crucible 12. A heating furnace 15 having a discharge outlet 15 'formed on a surface thereof and connected to an outlet 11b of the inner crucible 11; A lid (16) positioned above the heating furnace (15) to seal an upper surface of the heating furnace (15); A gas discharge pipe 17 installed perpendicular to the lid 16 to discharge gas generated from the inner crucible 11; And a nitrogen supply pipe 18 installed at the lid 16 to supply nitrogen gas to the inner crucible 11.

Here, the heat-resistant ceramic forming the inner crucible 11 is formed by mixing magnesium oxide (MgO), which is a main material, with aluminum oxide (Al ₂ O ₃ ), silicon dioxide (SiO ₂ ), and unavoidable impurities. As a specific composition, magnesium oxide (MgO) 85 to 98% by weight, aluminum oxide (Al ₂ O ₃ ) 0.5 to 12.0%, silicon dioxide (SiO ₂ ) 0.2 to 1.5%, and a small amount of titanium oxide (TiO ₂ ) And inevitable impurities such as zirconium oxide (ZrO ₂ ) and calcium oxide (CaO), and the heat-resistant ceramic powder is sintered to form the heat-resistant crucible 11.

And it is natural that the heating furnace 15 and the lid 16 should be made of a refractory brick that can withstand high temperatures. In addition, at least two gas discharge pipes 17 are installed, and a handle 19 for connecting the upper portion thereof is provided to open and close the lid 16.

In addition, the outlet 15 'of the heating furnace 15 has an inner circumferential surface formed in a wedge shape. This is to prevent the molten liquid discharged through the outlet 11b of the inner crucible 11 from sticking to the wall surface of the outlet 15 'during the discharge process.

On the other hand, the bone powder melting crystallization apparatus of the present invention is installed below the bone powder melting crucible furnace 10 and the bone powder melting crucible 10 to cool the melt liquid falling from the bone powder melting crucible furnace 10. It is configured to include a cooling transfer member 20 to be delivered to the collection vessel 30 after crystallization by crystallization, most of the other devices and controls related to cooling, such as a cooling device and a blower is already known because The description will be omitted.

The cooling transfer member 20 is installed at an angle to be inclined and arranged in a zigzag form in a plurality of cooling tracks 21 and a plurality of round bars continuously installed in the width direction on the upper surface of the cooling tracks 21. 22, a hole 23 'through which the bone powder melt passes, and a case 23 on which the cooling track 21 is fixed, and an inclined portion below the end of the lowermost cooling track, the collection container ( 30) and a discharge guide plate 24 for discharging crystals, and a vibration generator 25 installed below the case 23 to generate vibration in the case.

Here, the vibration generator 25 is a vibrator (25a) is installed in the lower portion of the case 23, a plurality of springs (25b) are installed below the vibrator (25a) to elastically support the vibrator (25a) Is done. Therefore, the vibration of the vibrator 25a is transmitted to the case 23 but does not affect the bottom surface.

In addition, the cooling track 21, the end is bent inclined upwardly to form a drop induction portion (21a), the uppermost cooling track of the cooling track 21 is the round bar 22 to a portion downstream of the melt falling point The drop guide piece 21b which is formed of the flat plate which is not provided and which drops a melt liquid to the downstream side in which the round bar 22 was provided is provided in the edge part of a flat plate part.

The crucible for melting bone powder of the present invention configured as described above and the bone powder melting crystallization apparatus using the same make a crystal having a color of bone powder itself by rapidly melting bone powder remaining after cremation of a dead body.

After putting about 2 kg of bone powder into the inner crucible 11 and covering the lid 16 to seal it, supplying power to the heater coil 14 for heating and supplying the inner crucible 11 through the nitrogen supply pipe 18. To supply nitrogen. Accordingly, heat is generated in the heater coil 14 for heating, and the external crucible 12 made of graphite material is heated by the heat. At this time, since the heating furnace 15 provided with the heating heater coil 14 and the external crucible 12 are spaced apart, the external crucible 12 is heated by convective heat and radiant heat.

Thereafter, the inner crucible 11 formed of heat-resistant ceramic is heated by heat generated in the outer crucible 12. In this case, the outer crucible 12 and the inner crucible 11 are spaced apart, so that the inner crucible 11 is heated by convective heat and radiant heat, and the internal temperature of the inner crucible 11 rises to about 2300 ° C. Done.

Therefore, the bone powder introduced into the inner crucible 11 is melted by high heat and changed into a liquid phase. At this time, since the melting point of calcium phosphate, the main component of bone meal, is 1670 ° C., the bone meal melts rapidly when exposed to ultra high heat of about 2300 ° C. In addition, nitrogen is supplied to the internal crucible 11 through the nitrogen supply pipe 18 so that the reaction is performed under a nitrogen atmosphere so that bone powder is not oxidized. In addition, the odor component and gas generated in the process of melting the bone powder is discharged through the gas discharge pipe 18 so that the odor component is not contained in the bone powder melt.

Thereafter, the bone powder melt formed by melting the bone powder exits through the outlet 11b formed at the lower end of the inner crucible 11 and falls through the bottom outlet 15 'of the heating furnace 15. At this time, since the wedge shape is formed in the inner circumferential surface of the outlet 15 ', the bone powder melt is attached to the inner circumferential surface of the outlet 15' due to the wedge shape of the inner circumferential surface of the outlet 15 'even when the bone powder melt is discharged in a twisted form. Will not be.

Bone powder melt discharged through the outlet 15 'falls to the flat portion of the uppermost cooling track of the cooling track 21 through the hole 23' formed in the case 23 of the cooling transfer member 20 at the lower portion thereof. do. At this time, since the cooling track 21 is inclined and the case 23 is vibrated up and down by the vibration generator 30, the bone powder melt flows along the cooling track 21 oscillating up and down. Thereafter, the drop guide piece 21b provided at the end of the flat plate portion of the uppermost cooling track falls to the upper side of the round bar, and is formed into a sphere by surface tension during the dropping process.

Subsequently, the bone powder melt gradually flowing along the cooling track 21 on which the round bar 22 is installed is gradually cooled and solidified, and the drop induction part 21a formed at the end of the cooling track 21 is used for the next cooling track. It falls to the upper surface. Repeating this process deforms into a sphere due to the surface shape of the round bar 22 and the surface tension of the bone powder crystals before the bone powder crystals formed by cooling the bone powder melt are completely hardened.

In addition, since it is cooled by the cold wind blown from the blower (not shown), it gradually solidifies from the outer surface. Subsequently, the solidified bone powder melt is gradually moved along the inclined surface of the cooling track 21 and solidified to the inside thereof to form crystals, ie, saris, of the same color as the bone powder. The crystals are transferred along the plurality of cooling tracks 21 arranged in a zigzag form, and then collected in the collecting container 30 by discharge guide plates provided under the cooling tracks 21.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Changes will be possible.

1 is a schematic view showing a conventional bone melt melting crystallization apparatus.

Figure 2 is a block diagram illustrating a crucible furnace for melting bone powder according to the invention.

Figure 3 is a conceptual diagram of bonding to the crucible for melting bone powder of the present invention.

Figure 4 is a schematic view showing a cooling track which is a main component of the bone powder melt crystallization apparatus according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: Crucible melting furnace

  11: inner crucible 12: outer crucible

  13: mounting ring 14: heater coil for heating

  15: heating furnace 16: lid

  17: gas discharge pipe 18: nitrogen supply pipe

20: cooling transfer member

  21: cooling track 22: round bar

  23: case 24: discharge guide plate

25: vibration generator

  25a: vibrator 25b: spring

30: collection container

Claims (6)

The outlet 11b through which the bone powder injected into the interior through the upper opening 11a is melted and discharged is formed at the bottom, and the lower portion is formed in a funnel shape which is connected to the outlet 11b, and has a cylindrical shape made of a heat-resistant ceramic material. An inner crucible 11; An outer crucible (12) of graphite material in which the inner crucible (11) is accommodated in a state in which an inner circumferential surface and an outer circumferential surface of the inner crucible (11) are spaced to some extent; It is integrally attached to the upper end side of the inner crucible 11 and is mounted on the upper surface of the outer crucible 12 to support the bottom of the inner crucible 11 to be positioned higher than the bottom of the outer crucible 12. A ring 13; A heater coil 14 for heating is provided therein, and the outer crucible 12 is accommodated in a state where an inner circumferential surface and an outer circumferential surface of the outer crucible 12 are spaced to some extent, and a bottom for supporting the outer crucible 12. A heating furnace 15 having a discharge outlet 15 'formed on a surface thereof and connected to an outlet 11b of the inner crucible 11; A lid (16) positioned above the heating furnace (15) to seal an upper surface of the heating furnace (15); A gas discharge pipe 17 installed perpendicular to the lid 16 to discharge gas generated from the inner crucible 11; Crucible for melting the bone powder, characterized in that it comprises a; is provided on the lid (16) for supplying nitrogen gas to the inner crucible (11). The method of claim 1, The heat-resistant ceramic forming the internal crucible 11 is for melting bone powder, characterized in that the magnesium oxide (MgO) as the main material is formed by mixing aluminum oxide (Al ₂ O ₃ ), silicon dioxide (SiO ₂ ) and inevitable impurities By the crucible. The method of claim 1, The outlet 15 'of the heating furnace 15 is a crucible melting furnace, characterized in that the inner peripheral surface is formed in a wedge shape. The melted melting crucible furnace 10 according to any one of claims 1 to 3 and the melt liquid which is provided below the bone flour melting crucible 10 and falls from the bone flour melting crucible 10 After cooling to crystallize and transfer to the transfer container 20 to the collection container 30, The cooling transfer member 20 is installed at an angle to be inclined and arranged in a zigzag form in a plurality of cooling tracks 21 and a plurality of round bars continuously installed in the width direction on the upper surface of the cooling tracks 21. 22, a hole 23 'through which the bone powder melt passes, and a case 23 on which the cooling track 21 is fixed, and an inclined portion below the end of the lowermost cooling track, the collection container ( 30) and a discharge guide plate (24) for discharging the crystals, and the bone powder melt crystallizer, characterized in that it comprises a vibration generator (25) installed in the lower portion of the case (23) to generate vibration in the case. 5. The method of claim 4, The vibration generator 25 is composed of a vibrator (25a) is installed on the lower portion of the case 23, a plurality of springs (25b) are installed on the lower portion of the vibrator (25a) to elastically support the vibrator (25a) Bone powder melt crystallization apparatus, characterized in that. 5. The method of claim 4, The cooling track 21, the end is bent upwardly inclined to form a drop induction portion 21a, The topmost cooling track of the cooling track 21 is formed as a flat plate without the round bar 22 up to a part downstream of the melt dropping point, and the melt is dropped to the downstream side where the round bar 22 is installed at the end of the flat plate part. Bone powder crystallization apparatus characterized in that the drop guide piece (21b) to be installed.

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