KR101090585B1 - Apparatus for crystallizing powdered bones - Google Patents

Abstract

The present invention relates to an apparatus for crystallizing after heating and melting the ashes, the ashes crystallization device according to the present invention, the ashes powder is accommodated in the interior and melted, the lower portion is made of a funnel, the lower end of the outlet Equipped crucibles; Heating means for heating the crucible; A stopper shaft having a cylindrical shape penetrating through the center of the crucible and having a groove formed at a lower portion thereof so as to rotate the lower portion to open and close the outlet of the crucible; A discharge pipe communicating with the discharge port of the crucible to discharge the melt; And curing means for receiving and curing the molten liquid from the discharge pipe.

According to the present invention, the stopper shaft does not move in and out of the crucible as compared to the stopper for opening and closing the outlet of the crucible by opening and closing the outlet by the rotational movement to increase the thermal efficiency, the fixed position There is an effect that the stability of the apparatus is increased by performing only the rotational motion at.

Description

Apparatus for crystallizing powdered bones}

The present invention relates to an apparatus for crystallizing after heating and melting the ashes.

As a conventional technique of melting and solidifying ash powder, a method using a high frequency (Korean Patent No. 0585202), a method of injecting and melting a flame using a high-temperature burner (Korean Patent No. 0562722), a pyrolysis gasification melting method And melting using concentrated oxygen or CO ₂ and CO gas (Korean Patent Application No. 2003-0022896), a method of making crystals using a flame generated from a mixed gas of LPG gas and oxygen (Registered Patent No. 0445338), a method of melting by arc discharge using a plasma torch (registered patent No. 0439684), a method of melting bone powder with a flame using a brown gas mixed with hydrogen and oxygen (patent application No. 2005-0034355), Method of melting bone powder of flame method using gas, electric furnace method using supercantal or silicon rod and induction furnace method using high frequency (Patent application 1999-0017268) There are dogs.

In addition, as a method of forming the shape after melting the bone powder, "3 to 5% by weight of barium carbonate and 2 to 3% by weight of lime is added, and then the bone powder is melted with a flame and then the liquid bone powder is A method of forming a spherical crystal or injecting it into a forming mold by cooling it while dropping and atomizing it while dropping it on a diaphragm is disclosed in Korean Patent No. 0407145. Method for molding the processing method using the "Korean Patent Registration No. 076326," The mixture of bone flour and mineral mixture and melted with a flame and drop the crystals into the passage to make a circle to 400 ℃ 1 It is disclosed in Korean Patent No. 0269981, which is a method of producing a crystal by heat treatment for ˜2 hours, and using a high frequency induction heating generator, How and at the same time using the intermittent opening and closing rod yungche the separation at a predetermined interval using the air nozzle to the exit, "it is disclosed in Korea Patent Registration No. No. 0,549,827.

A stopper for opening and closing the outlet of the crucible is used to discharge the molten ash powder from the crucible by a predetermined amount. The stopper according to the prior art uses a method of opening and closing the outlet by vertical movement in terms of heat transfer and device stability. There is a problem of inefficiency. In addition, according to the prior art, there is a problem that the shape of the crystal is monotonous, and the operation of the curing apparatus is complicated to form crystals of various shapes.

The present invention has been made to solve the above problems, and provides a bone ash crystallization device that increases the efficiency of heat transfer and mechanism stability by allowing the stopper for opening and closing the outlet of the crucible to open and close the outlet by the rotational movement. The purpose.

Another object of the present invention is to provide a bone ash crystallization apparatus capable of forming crystals of various shapes by an easy operation by providing various accommodation grooves in at least one hardened plate installed on a support moving on a rail.

In order to achieve the above objects, the ashes crystallization apparatus according to the present invention, containing the ashes therein and melted, the bottom is made of a funnel, the bottom of the crucible having an outlet; Heating means for heating the crucible; A stopper shaft having a cylindrical shape penetrating through the center of the crucible and having a groove formed at a lower portion thereof to open and close the outlet of the crucible; A discharge tube communicating with the discharge port of the crucible to discharge the molten liquid; And curing means for receiving and curing the molten liquid from the discharge pipe.

In the ash bone crystallization apparatus, the curing means is provided in the form of a disk, at least one hardened plate having a plurality of receiving grooves for receiving and curing the molten liquid discharged through the discharge pipe.

In the bone ash crystallization apparatus, a plurality of receiving grooves of the hardening plate are arranged to form at least one concentric circle, and the boundary of the mountain is formed between the concentric circles.

In the ashes crystallization apparatus, the at least one hardened plate is installed on a support moving on a rail.

In the bone ash crystallization apparatus, each of the at least one hardened plate is provided with a hardened body discharge plate on one side.

In the ash dust crystallization apparatus, the heating means is at least one magnetron for generating a microwave for heating the crucible.

In the ash bone crystallization apparatus, the stopper shaft is driven by a first motor.

In the ash bone crystallization apparatus, a portion located inside the crucible of the stopper shaft is made of zirconium dioxide, and a portion connected to the gear connected to the first motor is made of stainless steel.

In the ashes crystallization apparatus, each of the at least one hardened plate is rotated by a second motor.

According to the present invention as described above, as the stopper for opening and closing the outlet of the crucible by opening and closing the outlet by the rotational movement, the stopper shaft does not move in and out of the crucible as compared to the way to open and close by the vertical movement, the thermal efficiency is increased, There is an effect that the stability of the instrument is increased by performing only the rotational movement in a fixed position.

In addition, the present invention is provided with a variety of receiving grooves in one or more hardening plate installed on the support moving on the rail, there is an effect that the operation of the mechanism required to form crystals of various shapes is concise.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the ashes crystallization apparatus 1 according to the present invention comprises a heating means, a crucible 20, a stopper shaft 30, a discharge pipe 40 and a hardening means.

In the present invention, the heating means include all types of heating devices for heating the crucible 20, but in a preferred embodiment of the invention the heating means comprises at least one of generating microwaves for heating the crucible 20. It is implemented with a magnetron 10.

Magnetron 10 uses about 5 to 10 relatively small power consumption of 1kW ~ 10kW to generate a microwave of 2.45GHz. In this case, when using 10kW of power, it is more economical and stable system design by using 10 1KW for microwave ovens used in homes rather than using expensive 10kW magnetron.

The crucible 20 accommodates and melts the ashes therein, has a funnel shape at the bottom, and has an outlet 29 at the bottom. When using the magnetron 10 as a heating means in a preferred embodiment of the present invention, the crucible 20 is composed of a dual structure of exothermic crucible and melting crucible.

The heating crucible is made of SiC material and generates heat by the microwave generated by the magnetron 10, and a lower portion thereof forms a tapered shape. In the present invention, the selection of the material for the exothermic crucible has an important meaning. In the case of the metal, since the microwave reacts very vigorously, it is not used, and several hundreds to thousands of ohms of SiC are used. When using general SiC, it oxidizes at 1,400 ℃, but high temperature SiC material sintered at high temperature can be used at 1,650 ℃. At this time, since SiC is not an active heating element but a passive heating element, even if partially oxidized, there is no big problem to use.

The melting crucible is installed in close contact with the inside of the exothermic crucible and accommodates the ashes, and is heated by heat transfer by the exothermic exothermic crucible to melt the ashes. Any one of Al ₂ O ₃ , MgO, and ZrO ₂ You can use At this time, the melting crucible is configured in a funnel shape so that the ashes can be sufficiently melted to escape to the lower portion, and forms a discharge port at a position slightly separated from the center of the lower end thereof. In addition, the melting crucible is preferably configured to maintain a maximum contact area with the exothermic crucible and the exothermic crucible so that sufficient heat transfer is achieved, and the thickness thereof is preferably 5 to 10 mm. In addition, since the microwaves react by oscillating the inside of the melting crucible, it must be electrically grounded, and it is preferable to install a temperature sensor inside the melting crucible to measure the crucible temperature.

The hole 22 is formed in the upper surface 21 corresponding to the crucible 20, the hole 23 is formed also in the upper part of the crucible 20, The hole 22 and the crucible upper part of the upper surface 21 are formed Between the holes 23 are communicated through the funnel 24 and the tube 25. When heating the crucible 20, it is preferable that a cover (not shown) is covered in the hole 22 of the upper surface. Here, the funnel 24 is preferably made of SUS or alumina and the tube 25 is preferably made of alumina. Since the bone ash input structure does not limit the scope of the present invention, it is a matter of course that the present invention may have various types of upper structure different from the above description.

The stopper shaft 30 has a cylindrical shape through which the rotation center is accurately supported by the hole 27 formed in the crucible lid 26 and the hole 28 formed at the center of the bottom of the crucible 20, thereby penetrating the center of the crucible 20. The groove 32 is formed at one side of the lower portion of the stopper shaft 30. The upper portion of the stopper shaft 30 is made of stainless steel and is connected to the gear 36 connected to the first motor 34 to receive the rotational force of the motor. The first motor 34 is sufficiently far from the crucible 20, fitted with a heat dissipation cover (not shown) and cooled in a forced air cooling manner by a cooling fan (not shown). The gear 36 connected to the first motor 34 is manufactured without a backlash. In addition, the portion located in the crucible 20 in the stopper shaft 30 is preferably made of zirconium dioxide (ZrO ₂ ).

As shown in FIG. 3A, the stopper shaft 30 blocks the outlet of the crucible 20, and as the stopper shaft 30 is rotated by the first motor 34, the stopper shaft as shown in FIG. 3B. If the groove 32 of the 30 is located at the outlet 29 of the crucible 20, the melt is discharged through the outlet 29.

The discharge pipe 40 communicates with the discharge port 29 of the crucible 20 to discharge the melt, which is installed in close proximity to the crucible 20 to prevent the melt from being discharged from being cooled by flowing inside the discharge pipe 40. It is necessary to surround the surroundings with an insulation to keep warm.

The hardening means is a means for receiving the molten liquid from the discharge pipe 40 and curing. In the preferred embodiment of the present invention, the hardening device 50 having the hardened plate 52 provided on the support 62 moving on the rail 66. Is implemented. As shown in FIG. 4, the cured plate 52 has a plurality of receiving grooves 54 and 58 for accommodating and curing the molten liquid discharged through the discharge pipe 40 in the form of a disc. Receiving grooves are arranged to form at least one concentric circle, it is preferable that a mountain-shaped boundary 56 is formed between the concentric circles. In addition, one hardening plate may be installed on the support 62, but in some cases, two or more hardening plates may be installed as illustrated in FIGS. 5 and 6, and each hardening plate may include a hardened body discharge plate (one side). 60) can be installed.

The user moves the support base 62 on which the hardening plate 52 is installed on the rail 66 by turning the handle 64 provided in the hardening device 50 so that the desired accommodation grooves 54 and 58 of the desired hardening plate 52 can be moved. ) May be located just below the discharging pipe 40. Since each hardening plate 52 is rotated by the second motor 68, the molten liquid discharged through the discharge pipe 40 is sequentially accommodated in each of the receiving grooves 54, 58 and slowly cooled. The rotational speed by the second motor 68 may be determined by the speed at which the melt is discharged through the discharge pipe 40 and the number of receiving grooves 54 and 58 arranged in one concentric circle. The receiving grooves 54 and 58 of the hardened plate may have various shapes such as spherical shape, tetrahedron, cube, and star.

Hereinafter, the operation of the ashes powder crystallization apparatus 1 according to the preferred embodiment of the present invention will be described.

First, the ashes are put into the crucible 20 through the funnel 24 and the tube 25. Then, the funnel 24 is removed or the cover (not shown) is closed with the funnel 24 intact. Here, when using the funnel 24 as a ball, it is preferable that the material of the funnel 24 is alumina.

Thereafter, when the magnetron 10 is operated to generate microwaves, the exothermic crucible is generated by the microwave, and the exotherm of the exothermic crucible is transferred to the melting crucible. At this time, when the temperature of the melting crucible is 1500 ℃ or more, the ashes begin to melt. Until this time, the outlet 29 of the crucible 20 is kept blocked by the lower end of the stove shaft 30. When the ashes are at a temperature of 1600 ° C. or higher and the melt becomes water, the first motor 34 is automatically or manually operated. As the stop shaft 30 is rotated by the operation of the first motor 34, when the groove 32 of the stopper shaft 30 is positioned at the outlet 29 of the crucible 20, the melt liquid forms the outlet 29. Is discharged through. At this time, it is possible to control the amount of the melt discharged by adjusting the rotational speed of the first motor (34).

The melt liquid discharged from the crucible 20 through the discharge port 29 moves to the curing apparatus 50 through the discharge pipe 40. At this time, the user by moving the handle 64 provided in the curing device 50, the support plate 62 is installed on the hardened plate 52 is moved on the rail 66, the desired receiving groove 54 of the desired hardened plate 52 58 may be located directly below the distal end of the discharge pipe 40. Since the hardening plate 52 is rotated by the second motor 68, the molten liquid discharged through the discharge pipe 40 is sequentially received in each of the receiving grooves 54 and 58 provided in the hardening plate 52. When the molten liquid is filled in the concave grooves 54 forming one concentric circle, the user adjusts the handle 64 so that the receiving groove 58 or another accommodating groove of the other hard plate is formed in the discharge pipe ( 40) the support 62 can be moved on the rail 66 to be positioned at the distal end.

Between the grooves constituting the same concentric circle is connected between the grooves 54a so that the melt can be transferred to each other, and between the concentric circles of the accommodating grooves are formed with a boundary 56 of the mountain type, even if the handle is moved while the melt is discharged The molten liquid dropped to the boundary 56 can automatically enter the receiving grooves 54 and 58.

The molten liquid contained in the accommodating grooves 54 and 58 is slowly cooled, and the cured plate 52 and the cured body in which the melt is cured are separated from each other by different cooling due to different heat transfer coefficients and thermal expansion coefficients. When the cured body is completely cured, the cured body may be picked up from the receiving grooves 54 and 58 by using a separate tool. In this case, a small horizontal groove (not shown) may be provided around the receiving grooves 54 and 58 to easily pick up the cured product. The cured body having escaped the receiving grooves 54 and 58 is temporarily stored in the cured body reservoir 61 through the cured body discharge plate 60.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

1 is a view showing a schematic cross-sectional configuration of the ashes crystallization apparatus according to a preferred embodiment of the present invention,

2 is a view for explaining the operation of the ashes crystallization apparatus of FIG.

Figure 3a shows a state in which the crucible outlet is closed by the stopper shaft, Figure 3b shows a state in which the crucible outlet is developed by the stopper shaft,

Figure 4 is a perspective view showing the appearance of the cured plate according to the present invention,

FIG. 5 shows how two hardening plates on a support move on a rail,

FIG. 6 is a diagram illustrating a cross-sectional configuration of the curing means of FIG. 5.

* Explanation of symbols for the main parts of the drawings

1: ashes powder crystallization device

10: magnetron 20: crucible

29 outlet 30 stopper shaft

32: groove 40: discharge pipe

50: curing device 52: hardening plate

54,58: receiving groove 56: boundary

60: hardened body discharge plate 62: support

64: handle 66: rail

Claims (9)

delete delete delete Receiving and melting the ashes therein, the lower portion is made of a funnel, the bottom of the crucible having an outlet; Heating means for heating the crucible; A stopper shaft having a cylindrical shape penetrating through the center of the crucible and having a groove formed at a lower portion thereof to open and close the outlet of the crucible; A discharge tube communicating with the discharge port of the crucible to discharge the molten liquid; And Hardening means for receiving and curing the molten liquid from the discharge pipe Including, The curing means Ash bone crystallization apparatus in the form of a disk, having a plurality of receiving grooves for receiving and curing the molten liquid discharged through the discharge pipe and provided with at least one hardening plate installed on a support moving on the rail. The method of claim 4, wherein each of the at least one cured plate Ash bone crystallization apparatus characterized in that the hardened body discharge plate is installed on one side. The method of claim 4, wherein the heating means Ash bone crystallization apparatus, characterized in that at least one magnetron for generating a microwave for heating the crucible. The method of claim 4, wherein the stopper shaft Ash bone crystallization apparatus, characterized in that driven by the first motor. The method of claim 7, wherein The portion located inside the crucible of the stopper shaft is made of zirconium dioxide, the portion connected to the gear connected to the first motor is bone ash crystallization apparatus, characterized in that made of stainless steel. The method of claim 4, wherein each of the at least one cured plate Ash bone crystallization apparatus, characterized in that rotated by a second motor.

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