KR20180037912A - Rotation freeze-drying apparatus and methods - Google Patents

Abstract

The present invention relates to a rotation freeze-drying apparatus, so as to measure a drying state of a material of to be rotation freeze-dried, which comprises an image acquisition unit to acquire a freeze-drying process stop image in a process of separating a material into an acquisition target material and an exclusion target material through a dehydration process by rotation of the material while sublimating moisture in frozen material by providing a vacuum environment in a pressure chamber in which a storage chamber containing the frozen material is accommodated. Therefore, a state of the material to be dried can be checked in real time.

Description

[0002] Rotation freeze-drying apparatus and methods [0003]

The present invention relates to a rotary freeze-drying apparatus, and more particularly, to a rotary freeze-drying apparatus for measuring a dry state of a rotary-type freeze-dried material in real time, maintaining a uniform temperature of the material, Freeze drying apparatus.

Adipose tissue metastasis to various parts of the body is a relatively common cosmetic, therapeutic and structural procedure involving the harvesting of adipose tissue from one site and the re-implantation of harvested and sometimes treated tissue at another site.

Adipose tissue metastasis has been used primarily for cosmetic defects such as facial folds, wrinkles, smallpox scars and divots, but recently cosmetic and / or therapeutic breast augmentation and reconstruction (Bircoll and Novack 1987; and Dixon 1988), and hip enlargement (Cardenas-Camarena, Lacouture et al. 1999, de Pedroza 2000 and Peren, Gomez et al.

In the past, fat tissue grafts and adipose tissue transplantation have been implicated in necrosis, body uptake and infection (Castello, Barros et al. 1999; Valdatta, Thione et al. 2001), calcification and scar formation (Huch, Kunzi et al. 1998), inconsistent engraftment (Eremia and Newman 2000), lack of durability, and other problems resulting from neovascularization defects and necrosis of implanted tissues.

One of the biggest challenges in adipose tissue metastasis is the transplant absorption by the body after metastasis and the maintenance of the volume of adipose tissue grafts. When fat tissue is harvested or washed, the space between individual pieces of harvested fat tissue is filled with a liquid (e.g., water, blood, Tumescent solution, oil).

When this tissue / fluid mixture is implanted into the recipient, the liquid portion is quickly absorbed by the body and volume loss occurs. The process of removing fluid from the tissue / fluid mixture is frequently referred to as adipose tissue drying or adipose tissue dehydration.

In addition, the content of erythrocytes, leukocytes, etc. in adipose tissue grafts may significantly affect the volume of grafts maintained after transplantation because of inflammatory reaction or deterioration. Another aspect of tissue maintenance is related to the amount of lipid in adipose tissue grafts. The presence of free lipid (meaning lipid released from dead or damaged fat cells) in adipose tissue grafts also causes inflammatory response or worsening of substantial phagocytic activity and consequent loss of graft volume I understand.

It has also been found that the mixing of concentrated populations of untreated adipose tissue and adipose-derived regenerative cells overcomes many of the problems associated with adipose tissue grafts and adipose tissue metastasis as described above.

However, isolation and purification of a concentrated population of adipose derived regenerative cells, including adipose derived stem cells (ADSC), usually involves a series of washing, digestion, filtration and / or centrifugation steps, which reduces viable cell yield And / or may require mechanical equipment and specialized clinicians and / or may impair the quality, appearance, longevity, hydration or efficacy of the graft.

In order to solve the above problems, there is a need for a device capable of removing the moisture from the substance while dewatering the substance to be excluded from the substance to obtain the substance to be obtained in the substance.

[0004] As shown in Korean Patent No. 10-1280159, a conventional technique for performing the above function is a vacuum evacuable vacuum chamber, an injection mechanism for injecting a raw material liquid containing the raw material into the evacuated vacuum chamber, A diffusion mechanism for at least diffusing the raw material on the shelf on the shelf by vibration, and an inclining mechanism for inclining the shelf so as to recover the raw material on the shelf The spreading mechanism includes a first vibration generator for vibrating the shelf when the shelf is in a horizontal state, and a second vibration generator for vibrating the shelf when the shelf is in an inclined state.

However, the conventional technology has the following problems.

When the material is sprayed, it becomes frozen because it becomes a particle state, so that the drying state can not be confirmed in real time.

Further, since it is provided inside the freezing temperature, there is a problem that it is difficult to maintain a uniform temperature.

In addition, although there is a device for recovering the obtained substance, there is a problem that a device for collecting the substance to be excluded is not provided separately.

Korean Registered Patent No. 10-1280159. (June 24, 2013)

DISCLOSURE OF THE INVENTION An object of the present invention is to solve the above-mentioned problems of the prior art, and it is an object of the present invention to measure the dry state of a freeze-

Still another object of the present invention is to maintain the temperature of the material uniform.

In addition, another object of the present invention is to facilitate collection of substances to be excluded.

In order to solve such a problem, the rotary freeze-drying apparatus of the present invention provides a vacuum environment to a pressure chamber accommodating a storage chamber containing a frozen material to sublimate moisture in a frozen material, Separating the substance into a substance to be obtained and a substance to be excluded, wherein the accommodating chamber forms a collecting space in which centrifugal force of the frozen substance is concentrated by rotation, so that the substance to be excluded can be collected in the collecting space.

The rotary freeze-drying apparatus of the present invention provides a vacuum environment in a pressure chamber accommodating a storage chamber containing a frozen material to sublimate moisture from the frozen material and dehydrate the material through rotation of the material to exclude And an image acquiring unit for acquiring a freeze-dried hyperfine still image in the course of separating into a target substance.

The rotary freeze-drying apparatus of the present invention provides a vacuum environment in a pressure chamber accommodating a storage chamber containing a frozen material to sublimate moisture from the frozen material and dehydrate the material through rotation of the material to exclude And a constant temperature providing unit for providing a uniform temperature in a process of separating into a target substance.

According to the present invention, the water collecting space is formed with a discharge hole, and the substance to be excluded is discharged to the outside of the storage chamber.

According to the present invention, the water collecting space is formed at a position where the radius is long from the rotation center of the accommodating chamber to the outer periphery.

According to the present invention, at least one water collecting space is formed on the outer periphery of the accommodating chamber.

According to the present invention, one or more water collecting spaces are formed on the outer periphery of the accommodating chamber and are formed symmetrically with each other.

According to the present invention, the storage chamber is formed in a polygonal shape, and a collecting space is formed at each vertex.

According to the present invention, the accommodating chamber is formed in an elliptical shape, and a collecting space is formed on both sides having the longest length from the center of rotation to the outer periphery.

According to the present invention, the storage chamber is formed in a circular shape, and a collection space protrudes from the outer periphery.

According to the present invention, the accommodating space is formed on both sides of the accommodating chamber having the longest length from the rotation center to the outer periphery.

According to the present invention, the image acquiring unit includes a camera and a strobe flashing means.

According to the present invention, the constant-temperature providing unit may include a pressure chamber, a pressure chamber, a temperature holding member, and a temperature adjusting member installed in the outer chamber, do.

According to the present invention, the constant temperature providing unit generates radiant energy.

According to the present invention, any one of the thermoelectric element, the heat wire heater, the halogen lamp, and the LED is applied.

According to the present invention, the storage chamber is applied to a material having a surface reflectance of 50% or more so as to improve the conduction efficiency of radiant energy generated in the quench supply.

According to the present invention, a measurement unit that uses at least one of a radiative thermal conduction temperature sensor, an infrared temperature sensor, a thermal imaging camera, and a display unit for informing a temperature outside the pressure chamber to measure the temperature of the object substance or the substance to be excluded .

According to the present invention, the accommodating chamber is in the form of a mesh.

According to the present invention, any one of synthetic resin, glass, and metal is applied to the accommodating chamber.

According to the present invention, an absorption member is provided on the inner surface of the storage chamber to absorb the substance to be excluded.

According to the present invention, there is provided a rotation unit for transmitting a rotational force to the storage chamber, wherein the rotation unit is composed of a motor that is directly connected to a center of the rotor on which the storage chamber is seated to transmit rotational force.

According to the present invention, there is further provided a water collecting chamber provided outside the storing chamber for collecting a substance to be excluded scattered while being separated through a dewatering process, wherein the water collecting chamber A partition wall surrounding the outside is formed, a lower portion of the partition wall extends inward, a center is curved upward, and a receiving space is formed to collect the fluid flowing on the partition wall.

According to the present invention, there is further provided a water collecting chamber provided outside the storing chamber for collecting a substance to be excluded scattered while being separated through a dewatering process, wherein the water collecting chamber A barrier rib surrounding the outer periphery is formed and a slanting membrane extending obliquely to the inner periphery is formed on the upper portion of the barrier rib. The lower portion of the barrier rib extends inward and the center is curved upward to accommodate the fluid flowing on the barrier ribs. .

According to the present invention, there is further provided a water collecting chamber provided outside the storing chamber for collecting a substance to be excluded scattered while being separated through a dewatering process, wherein the water collecting chamber A partition wall surrounding the outside is formed and curved so as to narrow the upper portion of the partition wall. The lower portion of the partition wall extends inward and the center is curved upward to accommodate the fluid flowing on the partition wall.

According to the present invention, there is further provided a water collecting chamber provided outside the storing chamber for collecting a substance to be excluded scattered while being separated through a dewatering process, wherein the water collecting chamber is connected to the rotor so as to be rotatable, So that the liquid is not scattered to the outside.

The present invention provides a method for freeze-drying freeze-drying, comprising: a step of submerging moisture in a material by exposing a frozen material to a vacuum environment; a step of separating the material into a substance to be obtained and a substance to be excluded through dehydration through rotation of the frozen material; , And collecting the separated excluded substances.

The present invention provides a method for freeze-drying freeze-drying, comprising: a step of submerging moisture in a material by exposing a frozen material to a vacuum environment; a step of separating the material into a substance to be obtained and a substance to be excluded through dehydration through rotation of the frozen material; And measuring the degree of drying by measuring the temperature of the substance to be obtained and comparing it with an external temperature.

The present invention provides a method for freeze-drying freeze-drying, comprising: a step of submerging moisture in a material by exposing a frozen material to a vacuum environment; a step of separating the material into a substance to be obtained and a substance to be excluded through dehydration through rotation of the frozen material; , And a step of acquiring an image of the lyophilization process of the material and measuring the drying degree.

According to the present invention, there is further provided a process for providing a uniform temperature to a frozen material through a constant temperature providing unit during the process of sublimating the moisture of the frozen material.

According to the present invention, the frozen material may be selected from organic materials, biomaterials, fats, fatty materials, ECM, minerals, and culture media, or may be applied by combining one or more materials.

According to the present invention, the method further includes the step of hermetically packaging the object material for irradiation or disinfection with gamma rays.

As described above, the apparatus and method for freeze-drying freeze-drying according to one embodiment of the present invention are characterized in that the freeze- An image capturing unit or a sensor for capturing a still image, so that the state of the material to be dried can be confirmed in real time.

The rotary freeze drying apparatus and method of the present invention have the effect of shortening the drying time through the constant temperature providing unit in the process of separating the substance into a substance to be obtained and a substance to be excluded so that the temperature of the substance is uniformly maintained.

In addition, the apparatus and method for freeze-drying freeze-drying of the present invention further include a water collecting chamber installed outside the storing chamber for collecting a substance to be excluded, which collects the substance to be excluded scattered while being separated through a dehydrating process, The maintenance and durability of the battery can be improved.

1 is an enlarged cross-sectional view showing a first embodiment of a rotary freeze-drying apparatus of the present invention.
2 is an enlarged cross-sectional view showing a second embodiment of the rotary freeze-drying apparatus of the present invention.
3 is an enlarged cross-sectional view showing a third embodiment of the rotary freeze-drying apparatus of the present invention.
FIG. 4 is an enlarged cross-sectional view showing various embodiments of the collecting chapters of the rotary freeze-drying apparatus of the present invention. FIG.
5 is a sectional view showing various embodiments of a storage section of a rotary freeze-drying apparatus of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that, in the drawings, the same components or parts have the same reference numerals as much as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

FIG. 1 is an enlarged cross-sectional view showing a first embodiment of a rotary freeze-drying apparatus of the present invention, FIG. 2 is an enlarged cross-sectional view showing a second embodiment of a rotary freeze- FIG. 4 is an enlarged cross-sectional view showing various embodiments of the collecting chamber of the rotary freeze-drying apparatus of the present invention, and FIG. 5 is a view showing various embodiments of the storage section of the rotary freeze- Sectional view.

The freeze-drying method of the present invention is as follows.

The environment in which the freezing temperature and the vacuum state are maintained allows the moisture to be removed from the substance while separating the substance to be obtained and the substance to be excluded from the substance so as to obtain a lyophilized substance to be obtained.

For example, if the material is a fat obtained from a living body, water and free oil may be desorbed and dehydrated in the fat so that the lyophilized fat can obtain stem cells.

Here, the substance may be selected from organic materials, biomaterials, fats, fatty materials, ECMs, minerals and culture fluids, or may be applied in combination of one or more substances.

That is, there are three embodiments of the freeze-drying method.

The first embodiment is a process in which a material is brought into contact with dry ice to expose the material to a vacuum environment while keeping the material at a freezing temperature, thereby removing water from the material by sublimation and vacuum of the dry ice, The substance to be separated from the substance to be obtained and the substance to be excluded are separated.

The second embodiment is a process of pulverizing and mixing a substance and dry ice to expose the material and the culture liquid to a vacuum environment while having the freezing temperature, thereby removing water from the substance by sublimation and vacuum of dry ice, Through the dehydration process, the substance is separated into the substance to be obtained and the substance to be excluded and separated.

The third embodiment is a process of bringing a substance and a culture liquid into contact with dry ice, exposing the material and the culture liquid to a freezing temperature while keeping the freezing temperature of the substance, and thereby removing water from the substance by sublimation and vacuum of dry ice, The substance is separated from the substance to be obtained and the substance to be excluded from the substance through a spinning dehydration process.

The above-mentioned embodiment brings the material into contact with the dry ice, or the material is mixed with the dry ice by crushing, or the material and the culture liquid are mixed and then contacted with the dry ice.

The material has a freezing temperature through dry ice.

Then, when the material is exposed to a vacuum environment, moisture is desorbed from the material through sublimation phenomenon of dry ice.

In addition, when the substance is rotated, the substance to be obtained and the substance to be excluded from the substance are separated from the substance through dehydration, and the substance to be excluded is separately collected.

Specifically, a substance, dry ice, or the like is contacted or pulverized and mixed so that the material has its own freezing temperature.

Here, the pulverization of the material atomizes the particles of the material through a conventional pulverizer.

Here, the reason for crushing the material is to increase the contact surface area of the crushed particles of the dry ice with the material, thereby promoting the sublimation phenomenon of the dry ice so as to have an effective freezing temperature of the material.

Here, dry ice is a solid carbon dioxide produced by compressing gaseous carbon dioxide, and besides the function of giving a freezing temperature, a substance to be obtained extracted from a substance to be described later can form an environment for cultivation through carbon dioxide expressed by sublimation of dry ice.

As described above, when the material having a freezing temperature is placed in a space with a pressure lower than the triple point, the moisture contained in the material is sublimed into a gaseous state and dried.

That is, in the vacuum pressure condition, the water contained in the substance having the freezing temperature is sublimated and water is desorbed.

Freeze-drying is a three-dimensional drying method using a phase diagram of water, such as sublimation and freezing, using thermal properties and the vapor pressure of vacuum, to sublimate and remove the moisture of the material.

Such lyophilization has the function of lowering the water content per volume of the material through improvement of biochemical properties.

And a dehydration process is performed by rotating the material simultaneously with the lyophilization process.

The dehydration process can separate and separate the substance to be excluded from the substance to be excluded and the excluded substance separately.

The dehydration process separates the object substance and the substance to be excluded from the substance using the centrifugal force generated by rotating the substance.

As a result, the object to be obtained having a freeze-dried state can be obtained in a solidified state due to the desorption of moisture from the material, thereby improving the prevention of the deterioration of the object substance, the expiration date, and the storage property.

The solid matter to be obtained may be irradiated with gamma rays.

This is to minimize the transplantation rejection reaction during the transplantation of the target substance.

Further, differentiation and proliferation of the substance to be obtained can be controlled through low-level gamma irradiation.

First, as shown in Fig. 1, the rotary freeze-drying apparatus according to the present invention comprises three embodiments.

First, a vacuum environment is provided in the pressure chamber accommodating the accommodating chamber 100 containing the frozen material to sublimate moisture in the frozen material, and at the same time, dehydrate the material through the rotation of the material, .

At this time, the accommodating chamber 100 forms a collecting space 122 in which the centrifugal force of the frozen material is concentrated by the rotation, so that the exclusion target material can be collected in the collecting space.

Secondly, a vacuum environment is provided in the pressure chamber in which the accommodating chamber 100 containing the frozen material is accommodated to sublimate moisture from the frozen material, and at the same time, And an image acquiring unit for acquiring a freeze-drying excitation still image during the separation process.

Thirdly, a vacuum environment is provided in the pressure chamber accommodating the accommodating chamber 100 containing the frozen material to sublimate the moisture in the frozen material, and at the same time, dehydrating the material through rotation of the material, And a constant temperature providing unit for providing a uniform temperature during the separation process.

The specific configuration of the rotary freeze-drying apparatus 10 will be described below.

That is, the rotary freezing apparatus includes a housing chamber 100, a pressure chamber 200, and an image acquisition section 300.

At this time, the storing chamber 100 contains the frozen material 1 in which the substance to be obtained and the substance to be excluded are mixed. The accommodating chamber 100 may be a general container having an open top, but a mesh form is preferred.

The water collecting space 122 is formed at a position where the radius is long from the rotation center of the accommodating chamber to the outer periphery.

That is, the storage chamber 100 is formed in a polygonal shape, and a collecting space 122 is formed at each vertex.

Alternatively, the storage chamber 100 may be formed in an elliptical shape, and a collecting space 122 may be formed on both sides having the longest length from the center of rotation to the outer periphery.

Alternatively, the storage chamber 100 is formed in a circular shape, and a collecting space 122 is formed to protrude from the outer periphery.

As a result, the accommodating chamber 100 may have a cross-sectional shape of various shapes as described above, and the collecting space may be positioned at a long radius from the center of the accommodating chamber 100.

This is because when the frozen material is centrifugally separated from the object substance and the substance to be excluded by rotation of the storage chamber 100, the freezing material is formed on both sides having the longest length from the rotation center to the outer circumference of the storage chamber 100, So that the target substance can be collected in the space 122.

In the accommodating chamber 100, a discharge hole 123 is formed in the water collecting space 122, and the substance to be excluded is discharged to the outside of the housing chamber.

In addition, at least one water collecting space 122 is formed on the outer periphery of the accommodating chamber 100, and in particular, the water collecting spaces are mutually symmetrically formed.

In addition, the absorption member 121 may be provided on the inner surface of the housing chamber 100 to absorb the substance to be excluded.

Further, the accommodating chamber 100 containing the frozen material 1 provides a vacuum environment to the accommodated pressure chamber 200. At this time, the cover 210 is installed on the upper portion of the pressure chamber 200. Particularly, a vacuum line 251 is connected to one side of the pressure chamber 200, a collet trap 253 is provided to the vacuum line 251, and a first pump 255 is installed at the end of the vacuum line 251. As such, the frozen material 1 is provided with a vacuum environment to sublimate moisture from the frozen material.

And includes a rotating part 500 for transmitting a rotating force to the frozen material 1. [ The rotation unit 500 includes a motor 520 that directly transmits a rotational force to the center of the rotor 510 on which the housing chamber 100 is mounted.

And a water collecting chamber 600 installed outside the accommodating chamber 100 and collecting the exclusion target material scattered while being separated through a dehydration process.

As shown in FIG. 4, the water collecting chamber 600 can be applied in various shapes. 4 (a), the water collecting chamber 600 is formed with a partition wall 610 that surrounds the outside to prevent the exclusion of substances to be excluded by rotation, and the lower portion of the partition wall 610 extends inward, So that the accommodation space 630 is formed to collect the fluid flowing on the partition wall 610.

4B, the water collecting chamber 600 is formed with a partition wall 610 surrounding the outside to prevent the exclusion of the substance to be excluded, which is dewatered by rotation, and a curtain wall 620 is formed at an upper portion of the partition wall 610 so as to be inclined inwardly The lower portion of the partition wall 610 extends inwardly and the center thereof is curved upward to form a receiving space 630 to collect the fluid flowing through the partition wall 610.

4 (c), the water collecting chamber 600 is formed in a curved shape so as to narrow the upper portion of the partition 610, and a partition wall 610 surrounding the outside to prevent the exclusion of the substance to be excluded, which is dewatered by rotation, The lower part of the partition wall 610 extends inward and the center is curved upward to form the accommodation space 630 so that the fluid flowing through the partition wall 610 is collected.

In addition, as shown in FIG. 2, the water collecting chamber 600 is connected to the rotor 510 so that the water collecting chamber 600 can be rotated, and the liquid is not scattered to the outside through the curtain 620 at the centrifugal point.

A suction line 651 is installed on one side of the water collecting chamber 600, a drain bottle 653 is provided on the suction line 651, and a second pump 655 is provided on the end of the suction line 651 to discharge the substance to be excluded.

As a result, the rotary freeze-drying apparatus 10 of the present invention further includes a water collecting chamber 600 installed outside the storing chamber 100 for collecting the substance to be excluded, and collecting the substance to be excluded scattered while being dehydrated, Maintenance and durability of the apparatus are improved.

1 and 3, an image acquiring unit 300 for acquiring a freeze-drying excitation still image in a process of separating a substance into a substance to be obtained and a substance to be excluded through a dehydration process by rotation of the frozen substance 1 .

The image acquisition unit 300 includes a camera 310 and a strobe light flash unit 320. Further, a measurement unit using at least one of a radiant heat conduction temperature sensor, an infrared temperature sensor, a thermal imaging camera, and a display unit 270 for informing a temperature outside the pressure chamber 200 for measuring the temperature of the object to be obtained or the object to be separated is included.

As a result, the rotary freeze-drying apparatus 10 according to the embodiment of the present invention is capable of obtaining a freeze-dried temporary static image in the process of separating a substance into a substance to be obtained and a substance to be excluded, An image acquisition unit 300 or a sensor for checking the state of the material to be dried in real time.

Meanwhile, as shown in FIGS. 2 and 3, a vacuum environment is provided in the pressure chamber 200 accommodating the accommodating chamber 100 containing the frozen material 1 to sublimate moisture from the frozen material, and at the same time, And a constant temperature providing unit 400 for providing a uniform temperature in the process of separating the substance into a substance to be obtained and a substance to be excluded.

The constant-temperature providing unit generates radiation energy. In the present invention, any one of the thermoelectric element, the heat wire heater, the halogen lamp, and the LED is applied.

In addition, the apparatus for generating radiative energy may be applied to the constant temperature providing unit.

Accordingly, the accommodating chamber is applied to a material having a surface reflectance of 50% or more to improve the conduction efficiency of radiant energy generated in the quench supply.

The accommodating chamber may be made of synthetic resin, glass, or metal.

The reason for emitting radiant energy is to allow heat to be transferred through the path of light, thereby providing a constant temperature with a uniform distribution of heat and a wider area.

The temperature control unit 400 accommodates the pressure chamber 200 in the outer chamber 410, fills the temperature holding member 420 between the pressure chamber 200 and the outer chamber 410, installs the circulation line 430 on the outer side of the outer chamber 410, The temperature adjusting means 440 is installed.

In particular, the temperature holding member 420 may include at least one of a jacket-shaped fluid receiving portion, a thermoelectric element, a hot wire heater, a fluid transfer hose, and a refrigerant vaporizer between the pressure chamber 200 and the outer chamber 410.

In addition, the refrigerant vaporizer uses dry ice, a cover 450 is provided on the outer chamber 410, and a heat insulating material 460 is provided inside the outer chamber.

As a result, the rotary freeze-drying apparatus 10 of the present invention shortens the drying time through the constant temperature providing unit 400 in the process of separating the substance into the object substance to be obtained and the substance to be excluded, so that the temperature of the substance is uniformly maintained.

The rotary freeze-drying method according to the present invention will be described as follows.

The first embodiment includes a process of submerging moisture in a material by exposing the material 1 to a vacuum environment and a process of separating the material into a substance to be obtained and a substance to be excluded through a dehydration process by rotation of the freeze material, And collecting the separated excluded substances.

The second embodiment includes a process of submerging moisture in a material by exposing the material 1 to a vacuum environment and a process of separating the material into a substance to be extracted and a substance to be excluded through dehydration through rotation of the freeze material 1, And measuring the degree of drying by measuring the temperature of the substance to be obtained and comparing with the external temperature.

A process of submerging moisture from the material by exposing the frozen material 1 to a vacuum environment and a process of separating the material into a substance to be obtained and a substance to be excluded through dehydration by rotation of the frozen material 1, And a step of acquiring a drying process image and measuring the degree of drying.

In this case, during the process of sublimating the moisture of the frozen material 1, a process for providing a uniform temperature to the frozen material 1 through the constant temperature providing unit 400 is further included.

Furthermore, the frozen material 1 may be applied to a selected one of an organic material, a biomaterial, a fat, a fat material, an ECM, an inorganic material, a culture liquid, or a combination of one or more materials.

In addition, the method further includes a step of hermetically sealing the object material for irradiation or sterilization with gamma rays.

As used herein, the terms "substantially", "substantially", and the like are used herein to refer to a value in or near the numerical value when presenting manufacturing and material tolerances inherent in the meanings mentioned, Absolute numbers are used to prevent unauthorized exploitation by unauthorized intruders of the mentioned disclosure.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be clear to those who have knowledge of.

Description of the Related Art [0002]
1: frozen material 10: rotary freeze drying device
100: accommodating chamber 121: absorbing member
122: Collecting space 123: Exhaust hole
124: channel 200: pressure chamber
210: cover 300: image capturing unit
310: camera 320: scintillation means
400: Constant temperature providing unit 410: Outer chamber
420: temperature holding member 430: circulation line
440: Temperature control means 450: Cover
460: Insulation material 500:
510: rotor 520: motor
600: collecting chamber 610: partition wall
620: Shielding film 630:

Claims (31)

There is provided a process for separating a substance into a substance to be obtained and a substance to be excluded through a dehydration process by rotating the substance while submitting moisture from the frozen substance by providing a vacuum environment in a pressure chamber accommodating the containing chamber containing the freezing substance ,
Wherein the accommodating chamber forms a collecting space in which the centrifugal force of the frozen material is concentrated by the rotation so that the object to be excluded can be collected in the collecting space. The present invention provides a vacuum chamber in which a storage chamber containing a frozen material is accommodated and a vacuum environment is provided to sublimate moisture from the frozen material and to separate the material into a target material to be extracted and a material to be excluded through dehydration by rotation of the material, And an image acquiring unit for acquiring a dry exaggerated still image. A vacuum environment is provided in the pressure chamber in which the storage chamber containing the frozen material is accommodated to sublimate moisture in the frozen material and at the same time to separate the material into the object substance to be extracted and the substance to be excluded through dehydration by rotation of the substance, And a constant temperature providing unit for providing a predetermined temperature. The method according to claim 1,
Wherein the water collecting space is formed with a discharge hole, and the substance to be excluded is discharged to the outside of the storage chamber. The method according to claim 1,
The water collecting space
Wherein the storage chamber is formed at a position where the radius of the outer periphery is longer than the rotation center of the storage chamber. The method according to claim 1,
The water collecting space
Wherein at least one of the at least one storage chamber is formed at an outer periphery of the storage chamber. The method according to claim 1,
The water collecting space
Wherein at least one of the first and second housings is formed on an outer periphery of the accommodating chamber and is symmetrically formed. The method according to claim 1,
Wherein the accommodating chamber is formed in a polygonal shape, and a collecting space is formed at each of the vertexes. The method according to claim 1,
Wherein the storage chamber is formed in an elliptical shape, and a collecting space is formed on both sides having the longest length from the center of rotation to the outer periphery. The method according to claim 1,
Wherein the storage chamber is formed in a circular shape so that a collecting space protrudes from the outer periphery. The method according to claim 1,
Wherein the accommodating chamber has a collecting space formed on both sides having the longest length from the center of rotation to the outer periphery. 3. The method of claim 2,
Wherein the image acquiring unit includes a camera and a strobe flashing unit. The method of claim 3,
The constant-
Characterized in that the pressure chamber is housed in an outer chamber, a temperature holding member is filled between the pressure chamber and the outer chamber, a circulation line is installed outside the outer chamber, and a temperature adjusting means is provided in the circulation line. . The method of claim 3,
Wherein the constant-temperature providing unit generates radiant energy. The method of claim 3,
Wherein one of the thermoelectric element, the heat wire heater, the halogen lamp, and the LED is applied. The method of claim 3,
Wherein the accommodating chamber is applied to a material having a surface reflectance of 50% or more so as to improve the conduction efficiency of radiant energy generated in the quenching treatment. 4. The method according to any one of claims 1 to 3,
A measurement unit using at least one of a radiative thermal conduction temperature sensor, an infrared temperature sensor, and a thermal imaging camera to measure a temperature of a substance to be obtained or a substance to be excluded; and a display unit for indicating temperature outside the pressure chamber. 4. The method according to any one of claims 1 to 3,
Wherein the storage chamber is in the form of a mesh. 4. The method according to any one of claims 1 to 3,
Wherein the accommodating chamber is made of synthetic resin, glass, or metal. 4. The method according to any one of claims 1 to 3,
Wherein an absorption member is provided on an inner surface of the storage chamber to absorb the substance to be excluded. 4. The method according to any one of claims 1 to 3,
And a rotating part for transmitting rotational force to the accommodating chamber,
Wherein the rotating portion is made of a motor that is directly connected to a center portion of the rotor on which the accommodating chamber is mounted to transmit a rotating force. 4. The method according to any one of claims 1 to 3,
And a collecting chamber disposed outside the accommodating chamber for collecting a substance to be excluded scattered while being separated through a dehydrating process,
Wherein the water collecting chamber comprises:
A partition wall is formed to surround the outside so as to prevent the exclusion of the exclusion target material that is dewatered by rotation, and a lower portion of the partition wall extends inwardly and a center is curved upward to accommodate the fluid flowing through the partition wall. Freeze drying device. 4. The method according to any one of claims 1 to 3,
And a collecting chamber disposed outside the accommodating chamber for collecting a substance to be excluded scattered while being separated through a dehydrating process,
Wherein the water collecting chamber comprises:
A partition wall surrounding the outside is formed to prevent the exclusion of the exclusion target material that is dewatered by rotation, and a curtain film is formed at an upper portion of the partition wall so as to be inclined inwardly. The lower portion of the partition wall extends inward, Wherein a space is formed to collect the fluid flowing on the partition wall. 4. The method according to any one of claims 1 to 3,
And a collecting chamber disposed outside the accommodating chamber for collecting a substance to be excluded scattered while being separated through a dehydrating process,
Wherein the water collecting chamber comprises:
A partition wall surrounding the outside is formed to prevent the exclusion of the exclusion target material that is dewatered by the rotation, and the partition wall is curved so as to narrow the upper part of the partition wall. The lower portion of the partition wall extends inward, So that fluid flowing through the partition wall is collected. 4. The method according to any one of claims 1 to 3,
And a collecting chamber disposed outside the accommodating chamber for collecting a substance to be excluded scattered while being separated through a dehydrating process,
Wherein the water collecting chamber is connected to the rotor so that the water collecting chamber can be rotated, and the liquid is prevented from scattering to the outside at the centrifugal point through the screen. Exposing the frozen material to a vacuum environment to sublimate moisture in the material,
Separating the substance into a substance to be obtained and a substance to be excluded through a dehydration process by rotation of the frozen substance,
And collecting the separated substance to be separated. Exposing the frozen material to a vacuum environment to sublimate moisture in the material,
Separating the substance into a substance to be obtained and a substance to be excluded through a dehydration process by rotation of the frozen substance,
And measuring the degree of drying by measuring the temperature of the substance to be obtained and comparing it with an external temperature. Exposing the frozen material to a vacuum environment to sublimate moisture in the material,
Separating the substance into a substance to be obtained and a substance to be excluded through a dehydration process by rotation of the frozen substance,
And a step of obtaining an image of the lyophilization process of the material and measuring the degree of the lyophilization. 29. The method according to any one of claims 26 to 28,
During the process of sublimating the moisture of the frozen material,
Further comprising the step of providing a uniform temperature to the frozen material through the constant temperature providing section. 29. The method according to any one of claims 26 to 28,
Wherein the frozen material is selected from organic materials, biomaterials, fats, fatty materials, ECM, minerals, and culture media, or may be applied in combination with one or more materials. 29. The method according to any one of claims 26 to 28,
Further comprising the step of sealing and packaging the object material for irradiation or disinfection with gamma rays.

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