KR200414282Y1 - The Spindle plate Cooling system for an Apparatus Which use Preparing a Crystal of Remains - Google Patents

Abstract

The disclosed subject matter relates to an apparatus for preparing ashes crystals for melting cosmetic cremates into spherical crystals, and improving the apparatus for preparing ashes crystals of Korean Patent Application No. 05-76255 filed by the applicant. It relates to a rotating disk cooling structure of a bone crystal manufacturing apparatus.

The technical configuration of the apparatus for producing ashes crystals of Patent Application No. 05-76255 is that the rotating disc 10 has a hollow inside thereof so that one side of the cooling water pipe 60 through which the cooling water is discharged is located therein. The other side of the tube 60 is connected to the first pump 70 connected to the coolant reservoir 80 through a pipe while being located outside the rotating disc, and the discharge shaft 90 is disposed at the end of the rotating shaft 14 of the hollow rotating disc 10. One side end is located while the discharge pipe 90 is connected to the heat exchanger 100 and the second pump 72 connected through the pipeline, the heat exchanger 100 again through the coolant reservoir 80 and the pipeline Consists of the connected configuration, the cooling water contained in the coolant reservoir 80 by the pump of the first pump 70 is transferred to the hollow portion 12 in the rotating disc 10 by the cooling water pipe (60) to rotate the rotating disc 10 After absorbing the heat generated in the) by the head of the second pump (72) It is characterized in that it is configured to exit the rotating disc through the discharge pipe through the heat exchanger (100) to release heat to the outside and flow into the coolant reservoir (80) again to form one cooling cycle.

Ashes crystals, rotating discs, cooling water, heat exchangers

Description

The Spindle plate Cooling system for an Apparatus Which use Preparing a Crystal of Remains}

Figure 1 is a schematic configuration diagram showing the overall configuration of the apparatus for producing ashes crystals according to the prior art.

Figure 2 is an operating state perspective view showing the main portion operating state according to FIG.

Figure 3 is a schematic front view schematically showing a rotating disk cooling structure of the apparatus for producing ashes crystals according to the present invention.

4 is a side cross-sectional schematic configuration diagram according to FIG.

5 is an operating state diagram for showing the cooling water circulation process of the rotating disk cooling structure according to the present invention.

Figure 6 is another embodiment showing a rotating disk cooling structure of the apparatus for producing ashes crystals according to the present invention.

☆ Explanation of symbols on major parts of drawings ☆

10 ... rotation disc 14 ... rotation shaft

20 ... vibration container 30 ... support bracket

42.heating furnace 60 ... cooling water pipe

70,72 Pump 80 Coolant reservoir

90 ... Exhaust tube 100 ... Heat exchanger

The present invention relates to an apparatus for producing ashes crystals by melting the cremated ashes to produce spherical crystals. In particular, the apparatus for preparing ashes crystals of Korean Patent Application No. 05-76255 filed by the present applicant. It relates to a rotating disk cooling structure of the apparatus for producing ashes crystals improved.

In Confucian culture, such as Korea, people prefer burial rather than cremation because of filial thoughts and feng shui geography, which suggest that the bodies of their ancestors cannot be undermined. As the area of the cemetery increases with the limited land area, the absolute shortage of the cemetery and the decrease of the land use area are problematic. This phenomenon is caused by the lack of the cemetery in a country with a high population density and a narrow territory. It is deeply recognized as a serious social problem.

Recently, the country recommends cremation rather than burial as a way to solve this problem, and the cremation culture is rapidly spreading due to the revision of the Jangyo Act and the change of public awareness.

In cremation culture, the bone powder obtained through cremation is sprayed in a suitable place such as a mountain or a river to soothe the soul of the dead (called a mountain bone), or the bone powder is placed in a container called a crypt and stored and managed in temples or crypts. As a result, the bereaved family members visit them regularly and perform rituals, but in the case of the mountains, they may cause aversion to pollution and people around them, and because of the disconnection with the deceased, There is a situation. As a result, a cremation culture has been prevalent in the ossuary or temples using the latter ossuary, and the government is actively encouraging it.

However, when putting the cremated ashes into the ossuary and storing them in the ossuary, there is a difficulty in storing and storing the ashes, and because the ashes are visually unsightly, people may cause disgust and the bones in the ossuary state. When put and stored for a long time there was a problem that the ashes decay due to the growth of harmful microorganisms, such as mold, bacteria on the inner wall of the ossuary box due to the temperature difference from the outside.

Therefore, in order to solve the above problems, the ashes of the dead are melted at a high temperature, and then made into spherical crystals so that they can be placed and stored in the ossuary box, which is very easy to store and manage. The method of manufacturing crystals and the apparatus for producing ashes to prevent the ashes from spoiling even after a long time to encourage the makeup culture by eliminating the has been proposed and filed in the applicant.

That is, according to the configuration disclosed in the Republic of Korea Patent Publication No. 2002-91149, 10% by weight of the mineral mixture is mixed with 90% by weight of ashes, mixed with water, and put the blended compound in a heating furnace to melt at a high temperature after melting By discharging in the form, it is made to produce crystals in the form of droplets having a beautiful color and easy storage by the mineral mixture.

However, this conventional technique is because the bone melt discharged through the heating furnace is configured to allow spherical crystals to form naturally while being cooled by the air during the process of descending along the first passage member. The particle size of the crystal was not uniform, and if a large amount of melt was poured at once, the ash melt could not be dispersed properly and escaped through the passage member as agglomerate, so that the desired bead-shaped crystals could not be obtained. Therefore, in order to prevent agglomeration of the ash melt discharged through the furnace, the handle must be repeatedly operated to discharge the melt discharged from the furnace little by little, but this takes too long to produce the ash crystals. There was a problem because of inefficient.

Accordingly, the present inventors can use the centrifugal force of the rotating disc and the vibration of the vibrating vessel to make molten ashes discharged from the heating furnace into beautiful crystals in the form of droplets having a uniform particle size. An apparatus for producing bone crystals, which can be significantly shortened, has been previously filed through Korean Patent Application No. 05-76255, and the apparatus for producing bone crystals of the disclosed structure is shown in FIG. 1.

That is, the ash crystals manufacturing apparatus pre- filed as shown in FIG. 1 includes a heating furnace 42, a support shaft 43 supporting the heating furnace 42, and a rotary knob 44 connected to the support shaft 43. ), A heating mechanism 45 for heating the heating furnace 42, a housing 46 surrounding the components, and a rotation disc 10 provided below the outlet side of the heating furnace 42, The vibration container 20 surrounding the rotation disc 10 and vibrating according to the rotation of the motor 15, and the vibration vessel 20 including the rotation disc 10 on a predetermined height within the housing 46. It includes a support bracket 30 for supporting the position and the transfer passage 50.

The ash crystals manufacturing apparatus of the prior application configured as described above is bounced outwardly under the influence of the centrifugal force when it touches the rotating disc 10 when the ash melt falls from the heating furnace 42 to the rotating disc 10. As they go out, they have a uniform particle size and small beads to form beautiful crystals.

However, in the above-described prior art configuration, when the ash melt having a high temperature of 2000 ° C. or more passed through the heating furnace falls on the rotating disc 10, the surface temperature of the rotating disc 10 is increased to overheat, and the surface of the disc is overheated. There is a drawback that the ash melt sticks to it. As a result, there was a case in which the ash melt adhered on the rotating disc cooled and agglomerated out of the ash, and thus, marble-shaped crystals having a small particle size could not be obtained. In consideration of these problems, the surface of the rotating disc was coated with Teflon resin to enhance the heat resistance. However, since the ash melt discharged through the furnace is so hot, it has not been an effective solution to solve the above problems. .

The present invention was devised to solve the above problems in view of the above-mentioned conventional arts, and formed a hollow inside the rotating disc to allow the cooling water to be continuously circulated therein and at the same time a plurality of blow nozzles outside. By cooling the surface of the rotating disc to prevent the rotary disc from being heated abnormally due to the hot ash melt, furthermore, when the hot ash melt of 2000 ° C. or higher discharged from the heating furnace falls on the rotating disc, It is an object of the present invention to provide a rotating disk cooling structure of an apparatus for producing a bone crystal, which can be easily thrown out to the outside by centrifugal action without sticking on the surface of the disc to obtain a uniform particle size.

As a technical means for achieving the above object, the present invention is a bead by the centrifugal action of the furnace furnace for melting the cremated ashes at high temperature, and the ashes melt discharged through the furnace after being discharged from the outlet side of the furnace. In the ash crystals manufacturing apparatus consisting of a rotating disc for crystallization into a spherical shape, and the rotating disc is located inside and a vibration container formed with a discharge port on one side, the rotating disc is hollow in the interior to discharge the cooling water One side of the cooling water pipe is located inside, while the other side of the cooling water pipe is located on the outer side of the rotating disc and is connected to the first pump connected through the cooling water reservoir and the pipe. This discharge line is connected to a second pump connected through a heat exchanger and a conduit. The heat exchanger is configured to be connected again through the cooling water reservoir and the pipeline, the cooling water contained in the cooling water reservoir by the pump of the first pump is transferred to the inside of the rotating disc by the cooling water pipe to absorb the heat generated in the rotating disc Rotation of the ash crystal crystal manufacturing apparatus, characterized in that configured to form a single cooling circulation cycle is discharged to the outside while passing through the heat exchanger to the outside through the discharge pipe by the pump head of the pump and flows into the coolant reservoir again Provide disc cooling structure.

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

Figure 3 is a schematic front schematic view showing the overall configuration of the rotating disk cooling structure of the ash crystal manufacturing apparatus according to the present invention, Figure 4 is a schematic cross-sectional side view according to Figure 3, shown in the present embodiment The same reference numerals and names will be used for the same parts as the conventional configurations.

The rotating disc cooling structure of the apparatus for producing ashes crystals applied to the present invention is a heating furnace 42 for melting the cremated ashes at high temperature, and the ashes melt provided in the outlet side of the heating furnace and discharged through the heating furnace is subjected to centrifugal action. In the ash crystals manufacturing apparatus of the patent application No. 05-76255 including the rotating disc 10 to crystallize into a ball-shaped spherical body and the vibration container 20 in which the rotating disc 10 is located, the rotating disc The cooling structure capable of continuously cooling the rotary disc 10 on the 10 side is applied to prevent abnormal heating of the rotary disc 10 due to the hot ash melt.

With reference to the accompanying drawings 3 to 4 will be described in detail the cooling structure applied to the present invention.

As shown in FIGS. 3 to 4, the present invention provides a hollow rotating disc 10 that crystallizes the hot ash melt discharged from the furnace 42 into beads, and the hollow in the rotating disc 10. And a cooling water pipe (60) for introducing cooling water into (12).

The other end of the coolant pipe 60 is connected to the coolant reservoir 80 in which the coolant is stored, and the coolant is pumped between the coolant tube 60 and the coolant reservoir 80 to the hollow portion 12 of the rotating disc. A first pump 70 for supplying is provided. A portion of one end of the discharge pipe 90 is installed at the end of the rotating shaft 14 of the rotating disc 10, and a second pump for discharging the cooling water through the hollow portion of the rotating disc to the other end of the discharge pipe 90. 72 is provided, and the second pump 72 is connected to a heat exchanger 100 for releasing heat in the cooling water absorbing thermal energy to the atmosphere via the rotating disc 10.

More specifically, the rotating disc 10 is formed in one side inclined in one side is made of a hollow inside the cooling water pipe 60 is discharged the cooling water is located inside, while the other side of the cooling water pipe 60 is a rotating disc (10) It is located on the outside is connected to the first pump (70) connected to the coolant reservoir (80) through a conduit. In addition, one end of the discharge pipe 90 is located at the distal end of the hollow rotating disc 10 and the rotating shaft 14 so that the coolant absorbing heat via the rotating disc 10 may be discharged. The other end is connected to a second pump 72 which sucks the cooling water in the rotating disk 10 which absorbs heat while passing through the rotating disk 10.

In addition, the second pump 72 is connected to the heat exchanger 100 through a conduit (not shown), and the heat exchanger 100 is again connected to the coolant reservoir 80 through a conduit.

That is, according to the present invention of the above configuration, the coolant stored in the coolant reservoir 80 is transferred to the inside of the rotating disc 10 through the cooling water pipe 60 by the head of the first pump 70 to rotate the rotating disc ( 10) After absorbing the heat of the phase, the second pump (72) is discharged to the outside through the discharge tube 90 through the rotary disk 10 through the heat exchanger (100) to release the heat to the outside and then coolant again One cooling circulation cycle is introduced into the reservoir (80).

Reference numeral 30 denotes a support bracket for supporting the rotating disc and the vibrating vessel 20 surrounding the same in the apparatus, and 15 indicates a motor for transmitting driving force to the rotating shaft of the rotating disc by belt transmission or gear engagement.

Next look at the operation and effect of the present invention made of the configuration as described above.

5 is a view showing the operation of the rotating disk cooling structure according to the present invention, while the rotating disk 10 is rotated at a high speed in one direction by the motor 15 in a state inclined in one direction while being supported by the support bracket 30 Centrifugal force is applied to the ash melt pouring at a uniform flow rate from the furnace to crystallize the ash melt into small beads.

At this time, the inside of the rotating disc 10 is filled with the cooling water discharged through the end of the cooling water pipe 60 to always maintain a proper temperature without being affected by the conduction heat caused by the high temperature ash melt. As a result, the ash melt does not stick on the rotating disc and easily slides outward of the disc.

Looking at the circulation of the cooling water in detail, the cooling water stayed in the cooling water storage tank 80 by the pumping operation of the first pump 70 is introduced into the central arch 12 in the rotating disc 10 by the cooling water pipe (60). The rotating disc 10 is cooled.

At this time, since the rotation disc 10 is installed in a state inclined slightly in one direction by the bracket 30, the introduced cooling water continues to accumulate in the lower edge region of the rotation disc 10. When the fresh water height of the collected coolant reaches the height of the corner corner 13 where the rotating disc 10 and the rotating shaft 14 are connected, it naturally moves over and moves to the rotating shaft 14 side and collects there again. See also part 5).

Subsequently, the coolant accumulated in the hollow portion of the rotating shaft 14 is discharged to the outside through the discharge pipe 90 having one end of the rotary shaft end, which is discharged from the second pump 72. By pumping, the cooling water accumulated in the rotating shaft is sucked and forcedly sent to the heat exchanger 100. Therefore, the cooling water sent to the heat exchanger 100 discharges the heat energy stored therein to the outside through the place and is forced into the cooling water storage tank 80 by the pumping force of the second pump, thereby completing a cycle. .

That is, in the cooling water circulating process as described above, the cooling water stored in the cooling water storage tank 80 is transferred to the rotating disc 10 through the cooling water pipe 60 by the head of the first pump 70 to be rotated on the rotating disc. The heat-absorbing coolant absorbs the heat and exits the rotary disc 10 through the discharge pipe 90 by the lift of the second pump 72 and is sent to the heat exchanger 100 to pass through the outside. The low-temperature cooling water that releases heat and undergoes heat exchange is returned to the cooling water reservoir 80 to form one cooling circulation cycle. This cycle is repeated over and over again as the device is driven.

The present invention can continuously cool the rotating disc by the above-described cooling water circulation process, and as a result, it is possible to prevent the closed end such that the ash melt adheres on the rotating disc.

On the other hand, Figure 6 is a view showing another embodiment of the present invention, according to another embodiment shown therein includes all the components of the above-described embodiment. However, the present embodiment is different from the above-described embodiment in that the nozzle 120 is further provided above the rotating disc 10.

The nozzle 120 is installed at the end of a tube (connecting tube) extending from the actuator 110 installed on the bracket to supply a high pressure to the rotating disk, for example, an actuator such as wind or cooling water supplied from the actuator 110. By spraying, the surface of the rotating disc 10 can be cooled. Here, the actuator 110 may be selected and applied to the pump or pump.

According to another embodiment of the present invention, as the coolant (wind or coolant) sprayed from the nozzle 120 together with the cooling water circulation of the above-described embodiment, the inside and the surface of the rotating disc can be simultaneously cooled, thereby affecting high temperature. Abnormal heating of the receiving rotary disc can be prevented reliably.

In particular, when the fan is applied as the operating device 110, it is possible to expect the effect of removing foreign matters on the surface of the disk because it continuously blows the wind on the surface of the rotating disc 10, the melt adheres to the surface of the rotating disc Can be prevented as much as possible.

As described above, according to the rotating disk cooling structure of the apparatus for producing ashes crystals according to the present invention, the cooling disk is continuously circulated in the rotating disk and the rotating disk is not heated by a blow nozzle provided outside, so that a constant temperature is always maintained. It is possible to keep the rotating disc from being heated abnormally due to the hot ash melt, and furthermore, when the hot ash melt of 2000 ° C. or higher discharged from the furnace falls on the rotating disc, It can be easily thrown out to the outside by centrifugal action without sticking to it, so that ashes crystals having a uniform particle size can be obtained.

Although the present invention has been illustrated and described in connection with specific embodiments, it should be understood that the present invention may be variously modified and changed without departing from the spirit or the scope of the present invention provided by the following claims for utility model registration. It will be appreciated that those skilled in the art can easily know.

Claims (4)

Rotating furnace 42 for melting the cremated ash at a high temperature, and the ashes melted under the outlet side of the heating furnace 42 to be discharged through the heating furnace 42 to crystallize into beads in the shape of beads by centrifugal action. In the ash crystals manufacturing apparatus comprising a disc 10 and the vibration container 20 in which the rotating disc 10 is located, The rotating disc 10 has a hollow inside thereof, and one side of the cooling water pipe 60 through which the cooling water is discharged is located therein, while the other side of the cooling water pipe 60 is located outside the rotating disc and the cooling water reservoir 80. It is connected to the first pump 70 connected through a conduit, the end of the rotary shaft 14 of the rotary shaft 14, the discharge pipe 90 is located at one end while the discharge pipe 90 is the heat exchanger 100 ) Is connected to the second pump 72 connected through a conduit, and the heat exchanger 100 is again connected to the coolant reservoir 80 through a conduit, by the head of the first pump 70, the coolant reservoir 80 Cooling water contained in the) is transferred to the hollow portion 12 in the rotating disc 10 by the cooling water pipe 60 to absorb the heat generated in the rotating disc 10 and then lifted by the second pump 72. The heat is discharged to the outside of the rotating disc through the discharge pipe and passes through the heat exchanger 100 to release heat to the outside. And it is again introduced into the cooling water reservoir 80, a rotating disk structure of the cooling ashes crystal producing device being configured to achieve a circulating cooling cycle. The method of claim 1, The ash disc crystal manufacturing apparatus further comprises a nozzle 120 connected to the upper side of the rotating disc 10 via a pipe with an actuator 110 provided on one side while maintaining a predetermined distance from the rotating disc 10. Rotating disk cooling structure. The method of claim 2, Actuator 110 is a rotating disk cooling structure of the apparatus for producing bone crystals, characterized in that the motor 휀. The method of claim 2, The actuator 110 is a rotary disk cooling structure of the apparatus for producing bone crystals, characterized in that the pump.

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