KR101821261B1 - Lyophilization equipment - Google Patents

Abstract

The present invention relates to a lyophilization device. In the lyophilization device, a housing having an opening and closing door and a suction pipe is prepared. A hot air blower is installed at an inner rear surface of the housing. A sample dryer containing samples is inserted and combined in the housing. A vacuum pump connected to the suction pipe is prepared at one side of the housing. A cold trap for connecting the vacuum pump and the sample dryer is installed at an upper surface of the housing. When the vacuum pump operates, air in the sample dryer is forcibly sucked into the vacuum pump such that the inside of the sample dryer is maintained in a vacuum state. The samples discharge moisture based on sublimation in the sample dryer heated by the hot air blower. The moisture discharged from the samples is collected in the cold trap, and the samples are dried in the sample dryer. According to the present invention, a different form of the sample dryer which is inserted and combined in the housing can be selected and used depending on types and amounts of samples to be dried. Heat is transferred to an entire external area of the sample dryer to uniformly transfer the heat to the samples in the sample dryer. The sublimation of the samples is increased and the moisture is discharged quickly as the transfer efficiency of the heat increases. Therefore, the drying time is shortened and the reliability of the product is improved.

Description

Lyophilization equipment

The present invention relates to a freeze-drying apparatus, and more particularly, to a freeze-drying apparatus for drying a sample in a sample drier by heating a sample drier with hot air while forming an internal space of a sample drier accommodating the sample in a vacuum state .

Generally, the freeze-drying device is a device for drying foods, medicines or cells in food processing fields, pharmaceutical fields, biological fields, and the like.

In this case, the freeze-drying apparatus is a device for freezing an object at a low temperature and then reheating the object to be frozen to sublimate the moisture into water vapor to dry the object.

Patent Document 1 discloses a conventional freeze-drying apparatus, which comprises a vacuum chamber in which a door that can be opened and closed at one end in a hollow shape is formed, a partition for partitioning upper and lower spaces in the vacuum chamber, A cold trap circulating part provided under the vacuum chamber and circulating the refrigerant through a cold trap; a coolant circulating part installed in the lower part of the vacuum chamber so that one end thereof communicates with the inner space of the vacuum chamber, A vacuum pump for forcedly sucking the air in the chamber, and a tray portion provided on the upper surface of the partition and accommodating the sample in the upper portion.

Here, the sample is placed on the tray of the vacuum chamber, and the door is closed to seal the inner space of the vacuum chamber.

Thereafter, the coolant is circulated through the coolant circulation portion of the cold trap, and the coolant is circulated through the cold trap, so that the cool air is transferred to the tray portion through the through hole and the sample placed on the tray portion is cooled to a temperature below the predetermined temperature value.

At the same time, the vacuum pump forcedly sucks air in the vacuum chamber to change the space inside the vacuum chamber to a vacuum state, and further circulates the heating medium through the heating medium port, so that the heating medium port is heated by the heat- And the sample placed on the tray is sublimated to discharge moisture into the vacuum chamber.

At this time, the moisture in the vacuum chamber is trapped in the cold trap to change into a predetermined solid ice-like solid, and the gas is discharged to the outside of the vacuum chamber through the vacuum pump to dry the sample.

However, in the above-described Patent Document 1, the tray can not be freely changed in accordance with the type of the sample to be dried or the amount of the sample to be dried, the heating medium port is heated so as to be proportional to the amount of the heating medium to limit the heating temperature of the heating medium port, The amount of heat transferred to the tray portion is remarkably decreased and the time for drying the sample placed on the tray portion due to the decrease in the amount of heat is prolonged. When the tray portion can not be reached, the sample placed on the tray portion does not cause a sublimation action, so that the sample is not dried and the reliability of the product is deteriorated.

KR 10-2016-0111137 A

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a sample dryer in which a housing provided with an opening and closing door and a suction pipe, a hot air blower installed inside the housing, And a vacuum pump connected to the suction pipe at one side of the housing. When the vacuum pump is driven by providing a cold trap that connects the vacuum pump and the sample drier to the upper surface of the housing, air in the sample dryer is forcedly sucked The inside of the sample drier is maintained in a vacuum state, and at the same time, in the sample drier heated by the hot air, the sample discharges water by the sublimation action, and the moisture discharged from the sample is collected in the cold trap, And a freeze-drying device.

According to an aspect of the present invention, there is provided a freeze-drying apparatus including: a housing having a hollow shape having an opening and closing door on a front surface thereof and a suction pipe formed on an inner rear surface thereof; A hot air fan fixedly installed on an inner rear surface of the housing to radiate heat to the inner space of the housing; A sample dryer, which is inserted into the housing and accommodates the sample therein, and has a vacuum drain pipe formed on a rear surface of the vacuum drain pipe to be inserted into the suction pipe of the housing; A vacuum pump installed at one side of the housing and connected to a suction pipe of the housing to forcibly suck air through the suction pipe; And a cold trap fixedly installed on the upper surface of the housing to connect between the vacuum pump and the sample drier and collect moisture contained in the air sucked by the vacuum pump.

In the freeze-drying apparatus according to the present invention, the hot air is hollow and has a partition wall partitioning the upper and lower spaces therein, and has a first vent hole communicating with the lower space at the front surface, A case defining a second vent hole communicating therewith and having a third vent hole communicating with the upper space on a rear surface thereof; An air-cooled condenser installed in a lower space of the case and forming an air intake fan for forcibly supplying external air to the lower space on the rear surface thereof to heat external air flowing into the lower space; A compressor installed in the lower space and supplied with the gas refrigerant discharged from the cold trap to compress the gas refrigerant into high temperature and high pressure gas refrigerant and supply the gas refrigerant to the air cooling type condenser; And a cascade condenser installed in the lower space for condensing the gaseous refrigerant circulated in the air-cooled condenser into liquid refrigerant, and supplying the condensed liquid refrigerant to the cold trap.

In the freeze-drying apparatus according to the present invention, the hot air is provided in the front surface of the case with a circulating fan for forcibly circulating the air in the housing to the lower space, and at the rear end of the circulating fan, And an electric heater which is formed by bending in the space direction and heats the air forcedly circulated to the lower space.

In the freeze-drying apparatus according to the present invention, the sample dryer has a hollow, open front, a door which can be opened and closed at the front, a vacuum discharge pipe formed at the rear surface thereof, A chamber formed with a plurality of spaced apart support projections; And a shelf holding a sample on the upper surface of the chamber, wherein the shelf is held in a plate-like shape in the chamber, and the chamber is stacked in the chamber.

In the freeze-drying apparatus according to the present invention, the sample dryer includes: a frame frame inserted and coupled into the housing; A plurality of manifolds aligned in a row in the front of the frame frame; A flask connected to each of the manifolds to receive a sample therein; And a vacuum exhaust pipe connected to the vacuum pump at one end and connected to a plurality of the manifolds at the other end to discharge the air in the flask to the outside.

In the freeze-drying apparatus according to the present invention, the sample dryer may include: a chamber having a hollow opening with a front surface, a door capable of being opened and closed at the front, and a vacuum exhaust pipe formed at a rear surface thereof; And a partition wall formed to intersect with the inside of the chamber to form a lattice-shaped sample accommodation space.

According to the present invention, it is possible to select and use another type of sample drier to be inserted and coupled into the housing depending on the type of the sample to be dried and the amount of the sample. Heat is transferred to the entire area of the outer surface of the sample drier, And the heat transfer efficiency is increased. As a result, the sublimation action of the sample is increased, and the moisture is quickly discharged. Thus, the drying time is shortened and the reliability of the product is improved.

1 is a perspective view showing a freeze-drying apparatus according to the present invention.
2 is a rear perspective view of the freeze-drying apparatus according to the present invention.
FIG. 3 is an exploded perspective view of FIG. 1; FIG.
4 is a side cross-sectional view of a hot air fan of the freeze-drying apparatus according to the present invention.
5 is a perspective view illustrating a sample dryer according to a second embodiment of the present invention.
Fig. 6 is a rear perspective view of Fig. 5; Fig.
7 is a perspective view of a sample dryer according to a third embodiment of the present invention.
8 is a side sectional view of Fig. 7; Fig.

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

Referring to FIGS. 1 to 8, the housing 100 is hollow and has an opening / closing door 101 formed on a front surface thereof and a suction pipe 102 formed on an inner rear surface thereof.

The housing 100 removably accommodates the sample dryer 300 for drying the sample therein.

A through hole (not shown) for guiding the air in the housing 100 to the outside of the housing 100 is formed on the rear surface of the housing 100 through the third vent hole 211b of the hot air fan 200 do.

A plurality of through holes (not shown) are formed on the bottom surface of the housing 100 to allow external air to flow into the air-cooled condenser 220.

The hot air (200) is fixed to the inner rear surface of the housing (100), and radiates heat to the inner space of the housing (100).

The hot air (200) radiates heat to heat the sample dryer (300) installed in the housing (100).

The hot air fan 200 is hollow and has partition walls 213 for partitioning upper and lower spaces 211 and 212 therein and has a first vent hole 212a communicating with the lower space 212 A case 210 formed with a second vent hole 211a communicating with the upper space 211 and a third vent hole 211b communicating with the upper space 211 on the rear side,

An intake fan 213 is installed in the lower space 212 of the case 210 and forcibly supplies external air to the lower space 212 on the rear surface of the case 210, An air-cooled condenser 220 for heating,

A compressor 230 installed in the lower space 212 and supplied with the gas refrigerant discharged from the cold trap 500 to compress the gas refrigerant into high temperature and high pressure gas refrigerant and supply the compressed gas refrigerant to the air cooled condenser 220;

A cascade condenser 240 installed in the lower space 212 for converting the gas refrigerant circulated to the air cooling type condenser 220 into liquid refrigerant and supplying the condensed liquid refrigerant to the cold trap 500, .

The case 210 discharges the air in the lower space 212 into the inner space of the housing 100 through the first vent hole 212a.

The second vent hole 211a of the case 210 guides the air in the housing 100 to the upper space 211 and the third vent hole 211b guides the air in the upper space 211 And discharged to the outside of the housing 100.

The circulation fan 260 for forcibly circulating the air in the housing 100 to the lower space 212 is installed on the front surface of the case 210 and the circulation fan 260 is disposed at the rear end of the circulation fan 260 An electric heater 261 is further provided which is bent in the direction of the lower space 212 from the front surface of the case 210 and heats the forced circulation air to the lower space 212.

The electric heater 261 is operated by receiving external power.

Preferably, the temperature sensor 212b for measuring the temperature of the air in the lower space 212 is formed on the wall surface of the lower space 212 of the hot air fan 200.

When the air temperature drops below a predetermined temperature, the circulation fan 260 and the electric heater 261 are connected to each other by the temperature sensor 212b, The circulating air is heated by the electric heater 261 while the air in the housing 100 is forcibly circulated to the lower space 212 by driving.

The air-cooled condenser 261 is heated to a predetermined temperature by being supplied with the high-temperature and high-pressure gas compressed by the compressor 230.

The compressor 230 compresses the low-temperature low-pressure gas refrigerant discharged from the cold trap 500 into a high-temperature, high-pressure gas.

The sample dryer 300 is inserted into the housing 100 to receive a sample therein and a vacuum exhaust pipe 301 to be inserted into the suction pipe 102 of the housing 100 is formed on the rear surface of the sample dryer 300.

The sample dryer 300 forcibly discharges air through the vacuum discharge pipe 301 to maintain the internal space in a vacuum state.

In the sample dryer 300, it is preferable that the frozen sample is received.

The sample dryer 300 receives the heat emitted from the hot air blower 200 and is heated to sublimate the sample contained therein.

The sample dryer 300 may be manufactured in various shapes according to the type of the sample or the weight of the sample to be dried.

The sample dryer 300 according to the first embodiment includes a door 310a which is open in the front and which is open in the front, a vacuum exhaust pipe 301 is formed on the rear surface, A plurality of supporting projections 311 spaced at predetermined intervals in the direction of the substrate 310 and supporting the supporting projections 312 of the chamber 310 in a plate form and stacked in the chamber 310, And a shelf 320 for receiving the sample.

The chamber 310 is formed to be relatively smaller than the inner diameter of the housing 100 and spaced apart from the inner space of the housing 100 by a predetermined distance.

The chamber 310 receives heat emitted into the housing 100, and the outer surface of the chamber 310 is heated.

The door 310a seals the internal space of the chamber 310. [

The sample dryer 300 according to the second embodiment includes a mold frame 310 'inserted and coupled into the housing 100 and a plurality of manifolds 310' A flask 330 'connected to each of the manifolds 320' and containing a sample therein, a flask 330 'connected at one end to the vacuum pump 400 and at the other end to the plurality of manifolds 320' 'To discharge the air in the flask 330' to the outside.

It is preferable that the frame frame 310 'has a shape of "┌┐".

The manifold 320 'blocks or opens the forced discharge of air in the flask 330' to the vacuum pump 400.

Preferably, the flask 300 'is in the form of a glass tube with an open top.

The vacuum exhaust pipe 301 is bent downward and inserted into the suction pipe 102 of the housing 100.

The sample dryer 300 according to the third embodiment has a hollow shape with a front surface opened and a door 311 "which can be opened and closed at the front and a chamber 310" formed with the vacuum discharge pipe 301 at the rear side. And a partition wall 320 '' formed to intersect with each other in the chamber 310 'to form a lattice-shaped sample accommodation space 320a' '.

The door 311 "seals the internal space of the chamber 310 ".

The vacuum discharge pipe 301 forcibly discharges the air remaining in the chamber 310 "to change the internal space of the chamber 310 " to a vacuum state.

The vacuum exhaust pipe 301 is connected to the vacuum pump 400.

The front end and the rear end of the partition wall 320 "are formed at predetermined distances from the front and rear surfaces of the chamber 310 ".

The sample accommodating space 320a "may have the same or different diameters by the user.

The vacuum pump 400 is installed at one side of the housing 100 and connected to the suction pipe 102 of the housing 100 to forcibly suck air through the suction pipe 102.

The vacuum pump 400 forcibly sucks air in the sample dryer 300 through the suction pipe 102.

The vacuum pump 400 maintains the space in the sample drier 300 in a vacuum state.

The cold trap 500 is fixed on the upper surface of the housing 100 to connect the vacuum pump 400 and the sample drier 300 to collect moisture contained in the air sucked into the vacuum pump 400, do.

The cold trap 500 collects moisture contained in the air in the sample dryer 300 to solidify the moisture.

The upper part of the cold trap 500 is opened and closed, and the sample inserted into the cold trap 500 is cooled to a predetermined temperature.

The freeze-drying apparatus according to the present invention constituted as described above is used as follows.

Here, the sample dryer 300 is divided into the first, second, and third embodiments. In the following description, the sample dryer 300 according to the first embodiment will be described as an example.

First, the sample dryer 300 is selected according to the kind of the sample to be dried or the amount of the sample to be dried, and the sample is received in the sample dryer 300.

At this time, the shelf 320 provided in the chamber 310 of the sample dryer 300 is moved out of the chamber 310, and then the sample is placed on the shelf 320.

The shelf 320 on which the sample is placed is inserted into the chamber 310 so that the shelf 320 can be supported on the support recess 311 so that the plurality of shelves 320 ) Are laminated.

The sample placed on the shelf 320 is preferably a frozen sample. If the sample is to be frozen, the sample is placed on a tray (not shown) or the shelf 320, This tray or shelf 320 is inserted into the cold trap 500 for a predetermined time to cool the sample to a predetermined temperature.

Thereafter, the door 310a of the chamber 310 is closed so that the inner space of the chamber 310 is blocked from the outside. In this state, the chamber 310 is pushed into the inside of the housing 100, A vacuum exhaust pipe 301 formed on the rear surface of the chamber 310 is inserted into the suction pipe 102 of the housing 100.

When the vacuum pump 400 is driven, the air in the chamber 310 of the sample dryer 300 is sucked by the suction pressure of the vacuum pump 400 through the vacuum discharge pipe 301 and the suction pipe 102, and moves in the direction of the vacuum pump 400.

At this time, the air discharged through the suction pipe 102 of the housing 100 is moved to the vacuum pump 400 through the cold trap 500, so that the moisture contained in the air passing through the cold trap 500 Is trapped in the cold trap (500).

Here, the cold trap 500 receives the liquid refrigerant discharged from the cascade condenser 240 and is cooled by a heat exchange function, and then transfers the gas refrigerant to the compressor 230.

Particularly, the chamber 310 maintains a frozen state of the sample while the inner space is changed to a vacuum state, and at the same time, the hot air 200 is operated to radiate heat to the inner space of the housing 100, The outer wall of the chamber 310 is heated by the air circulated in the space between the chamber 310 and the chamber 310 and the heat is introduced into the inner space of the chamber 310 and transferred to the sample accommodated in the shelf 320 will be.

At this time, the air-cooled condenser 220 of the hot air fan 200 receives the high temperature and high pressure gas refrigerant discharged from the compressor 230, is heated by the heat exchange action, and then transfers the gas refrigerant to the compressor 230.

The forced air supplied to the lower space 212 of the hot air fan 200 by the suction fan 221 is heated to a predetermined temperature while passing through the air cooled condenser 220, And moves to the inner space of the housing 100 through the vent hole 212a to heat the outer wall of the chamber 310 of the sample dryer 300 inserted into the housing 100. [

Here, the air-cooled condenser 220 heats air flowing through a through hole (not shown) on the bottom surface of the housing 100.

At this time, the temperature of the air supplied to the lower space 212 is measured by the temperature sensor 212b. If the temperature of the air is lower than the predetermined temperature, the temperature sensor 212b detects the temperature of the circulating fan 260, And the electric heater 261 so as to drive the circulation fan 260 and the electric heater 261.

The air in the housing 100 is then re-introduced into the lower space 212 by the circulation fan 260 and heated by the electric heater 261 to raise the temperature, 212a to the inner space of the housing 100 and then circulated in the same manner as described above via the circulation fan 260. [

The temperature sensor 212b continuously measures the temperature of the air flowing into the interior space of the housing 100 through the first vent hole 212a. When the air temperature rises above the predetermined temperature, The driving of the circulation fan 260 and the electric heater 261 is stopped.

The air heated in the chamber 310 of the sample dryer 300 in the inner space of the housing 100 passes through the second vent hole 211a by the natural circulation method and flows into the upper space 211 And then discharged to the outside of the housing 100 through the third vent hole 211b and the through hole (not shown).

Then, the sample which has received the heat in the cooled state discharges moisture while causing the sublimation action, and this moisture is discharged to the vacuum exhaust pipe (not shown) by the vacuum pump 400 in a state of being exposed to the air in the chamber 310 301 and the suction pipe 102 to the cold trap 500.

At this time, moisture contained in the air passing through the cold trap 500 is collected in the cold trap 500, and then the moisture-removed air is discharged to the outside through the vacuum pump 400, The sample housed in the chamber 310 is dried.

In the above description, the sample is received on the shelf 320 inserted into the chamber 310 and the sample is dried. However, according to the user's intention, the sample drier of the second embodiment or the third embodiment The sample can be accommodated in the container 300 and dried.

That is, in the sample dryer 300 of the second embodiment, a plurality of the flasks 330 'contain samples to be dried and each of the flasks 330' is connected to the manifold 320 ' So as to seal the flask 330 '.

Thereafter, the mold frame 310 'is inserted into the housing 100 so that the vacuum exhaust pipe 301 connected to the manifold 320' is inserted into the suction pipe 102 of the housing 100 And in this state, the vacuum pump 400 is driven so that the suction pressure is formed in the vacuum discharge pipe 301.

At this time, when the flask 330 'and the vacuum exhaust pipe 301 are communicated with each other by operating the manifold 320', the air in the flask 320 is forcibly sucked through the vacuum exhaust pipe 301, The space inside the flask 330 'is changed to a vacuum state.

Here, the manifold 320 'is individually operated by a user to communicate or block the flask 330' with the vacuum discharge pipe 301.

In the sample dryer 300 of the third embodiment, the sample is received in the sample accommodation space 320a "formed by the partition wall 320" in the chamber 310 ", and the door of the chamber 310 " The chamber 310 '' is sealed with the inside of the chamber 310 '' and then the chamber 310 'is inserted into the housing 100. The vacuum exhaust pipe 301 of the chamber 310' And is inserted into the suction pipe 102 of the housing 100.

Thereafter, the air in the chamber 310 "is changed to a vacuum state by forcibly discharging the air to the vacuum pump 400 through the vacuum discharge pipe 301. Thereafter, And dries each sample contained in the sample accommodation space 320a ".

A sample dryer 300 for holding a sample in an internal space and maintaining a vacuum state is inserted into the housing 100 and the sample in the sample dryer 300 is dried by radiating heat into the housing 100 It is possible to selectively use another type of sample drier 300 inserted and coupled into the housing 100 according to the kind of the sample to be dried and the amount of the sample to be dried, Thus, the heat is uniformly transferred to the sample in the sample dryer 300, and the effect of sublimation of the sample is increased due to the increase in the transfer efficiency of the heat, so that the moisture is discharged quickly.

The above-described freeze-drying apparatus according to the present invention is not limited to the above-described embodiments, and any person skilled in the art may apply the present invention without departing from the gist of the present invention claimed in the following claims. There is a technical spirit to the extent that various changes can be made.

100: housing 101: opening / closing door
102: Suction tube 200:
210: case 211: upper space
211a: second vent hole 211b: third vent hole
212: lower space 212a: first vent hole
212b: temperature sensing sensor 213:
220: air cooling condenser 221: suction fan
230: compressor 240: cascade condenser
260: circulating fan 261: electric heater
300: sample dryer 301: vacuum outlet pipe
310: chamber 310 ': frame frame
310 ": chamber 310a: door
311: Supporting block 311 ": Door
320: shelf 320 ': manifold
320 ": partition wall 320a": sample accommodation space
330 ': Flask 400: Vacuum pump
500: Cold Trap

Claims (6)

A housing (100) having a hollow shape with an opening / closing door (101) formed on its front surface and a suction pipe (102) formed on its inner rear surface;
A fan (200) fixed to the inner rear surface of the housing (100) and radiating heat to the inner space of the housing (100);
A sample dryer 300 which is inserted into the housing 100 to receive a sample therein and a vacuum exhaust pipe 301 to be inserted into a suction pipe 102 of the housing 100 on a rear surface thereof;
A vacuum pump 400 installed at one side of the housing 100 and connected to the suction pipe 102 of the housing 100 for forcibly sucking air through the suction pipe 102; And
A cold trap 500 fixedly installed on the upper surface of the housing 100 to connect between the vacuum pump 400 and the sample drier 300 and collect moisture contained in the air sucked into the vacuum pump 400, ≪ / RTI >
The hot air (200)
A partition wall 213 partitioning upper and lower spaces 211 and 212 is formed in the interior of the upper space 212 and a first vent hole 212a communicating with the lower space 212 is formed on the front surface, A case 210 having a second vent hole 211a communicating with the upper space 211 and a third vent hole 211b communicating with the upper space 211 on the rear side;
An air intake fan 221 is installed in the lower space 212 of the case 210 and forcibly supplies external air to the lower space on the rear surface of the case 210. The air intake fan 221 for cooling the external air flowing into the lower space 212, A condenser 220;
A compressor (230) installed in the lower space (212) for receiving the gas refrigerant discharged from the cold trap (500) and compressing the gas refrigerant into high temperature and high pressure gas refrigerant and supplying the compressed gas refrigerant to the air cooling type condenser (220);
A cascade condenser 240 installed in the lower space 212 for converting the gas refrigerant circulated to the air cooling type condenser 220 into liquid refrigerant and supplying the condensed liquid refrigerant to the cold trap 500, ;
≪ / RTI > delete The method according to claim 1,
The hot air (200)
A circulation fan 260 for forcibly circulating the air in the housing 100 to the lower space 212 is installed on the front surface of the case 210. The circulation fan 260 is disposed at a rear end of the circulation fan 260, Further comprising an electric heater (261) bent in the direction of the lower space (212) from the front and heating the air forcedly circulated to the lower space (212). The method according to claim 1,
The sample dryer (300)
A plurality of puddle parts 311 spaced apart from each other in the vertical direction by a vacuum discharge pipe 301 formed on the rear surface of the door 310a which is openable and closable in front, A chamber 310 forming a chamber 310;
A shelf (320) which is held in a plate shape and which is supported by a support hole (312) of the chamber (310) and is stacked in the chamber (310) and receives a sample on the upper surface thereof;
Wherein the freeze-drying apparatus comprises: The method according to claim 1,
The sample dryer (300)
A frame frame 310 'inserted and coupled into the housing;
A plurality of manifolds 320 'aligned in the row direction on the front surface of the frame frame 310';
A flask 330 'connected to each of said manifolds 320' and containing a sample therein;
A vacuum exhaust pipe 301 connected to the vacuum pump 400 at one end and connected to a plurality of the manifolds 320 'at the other end to discharge the air in the flask 330' to the outside;
≪ / RTI > The method according to claim 1,
The sample dryer (300)
A chamber 310 '' formed with a door 311 'openable and closable in the front and having the vacuum discharge pipe 301 formed at the rear thereof; And
A partition wall 320 '' formed to intersect with the inside of the chamber 310 '' to form a lattice-shaped sample accommodation space 320a '';
The freeze-drying apparatus comprising:

Images