KR102389852B1 - Vacuum drying system using vibration - Google Patents

Abstract

The present invention relates to a vibration-type vacuum drying system. More specifically, to dry an object to be dried at a low temperature to protect the nutrients of the object to be dried and at the same time efficiently extract the nutrient solution of the object to be dried, the vibration-type vacuum drying system includes: a vacuum pump (100) provided to be driven by a driving motor (110); a vacuum tank (200) communicating with the vacuum pump (100) through a first vacuum pipe (120) to maintain a low-pressure vacuum state therein; a drying chamber unit (300) communicating with the vacuum tank (200) through a second vacuum pipe line (210), sealed with a drying casing (310), and provided with a receiving space (320) to receive an object to be dried therein; a heating ventilation unit (400) including an air fan (430) connected to the other end of a first conduit (410) of which one end is disposed in communication with the upper part of the drying chamber unit (300) and connected to the other end of the second conduit (420) of which one end is disposed at the lower part of the first conduit (410) to ventilate the drying chamber unit (300), and a heating means (440) provided to heat outside air sucked by the air fan (430); a cooling outlet (500) connected to the first conduit (410) and the second conduit (420) to cool humid air discharged from the drying chamber unit (300) and discharge moisture; and a control unit (600) provided to transmit a control signal to the driving motor (110), the heating ventilation unit (400), and the cooling outlet (500).

Description

Vibration type vacuum drying system { VACUUM DRYING SYSTEM USING VIBRATION }

The present invention relates to a vibration-type vacuum drying system, and more particularly, a vacuum pump, a vacuum tank, It relates to providing a vibration-type vacuum drying system including a drying chamber unit, a heating ventilation part, a cooling discharge unit, and a control unit.

Industrially used drying technologies include hot air drying, freeze drying, spray drying, etc., and an appropriate method is selected and used according to the object to be dried.

In any drying method, energy must be input to dry the object to be dried, and it takes a lot of time.

In the case of hot air drying, which is the most widely used, energy efficiency remains at about 30%, and it takes a lot of drying time, and there are problems that severe discoloration occurs when the drying object is vegetables.

In particular, in the case of various vegetables, fruits, grains, etc. that can be turned into food, storage properties are poor, so the need for drying treatment for storage and distribution is increasing.

And, in order to create a higher added value, it is necessary to dry the object to be dried so that the nutrients and the inherent color are not discolored.

However, in a structure for installing a heating wire, heat transfer by convection of air is not performed well in a vacuum or reduced pressure atmosphere, and heat transfer by conduction is mainly performed. There are problems such as incomplete drying. Furthermore, there are cases in which a problem such as sticking or burning of the object to be dried occurs in a portion close to the heating wire.

Korean Patent Publication No. 10-0729908 discloses a technique for using radiant heat for drying by installing a far-infrared lamp inside.

Even in the conventional technology using radiant heat as described above, a reflector is installed so that the radiant heat is in contact with the object to be dried evenly.

In addition, some techniques for installing plate-shaped far-infrared heat sinks between shelves have been proposed to improve drying efficiency. It is difficult to dry a thick object to be dried. In order to secure a sufficient working space and dry a thick object, the gap between shelves should be wide.

Republic of Korea Patent Publication No. 10-0729908 (registered on June 12, 2007) Title of invention: Vacuum dryer using far-infrared lamp

The technical problem to be achieved by the present invention is to solve the problems or necessity as described above, by drying the object to be dried in a low temperature state to protect the nutrients of the object and at the same time to efficiently extract the nutrient solution from the object. It is intended to provide a type vacuum drying system.

Another object of the present invention is to communicate with a vacuum pump 100 provided to be driven by a driving motor 110 and the vacuum pump 100 through a first vacuum pipe line 120 to maintain a low pressure vacuum state therein. The vacuum tank 200 and the vacuum tank 200 are communicated with the second vacuum pipe line 210, are sealed with a drying casing 310, and are provided with an accommodation space 320 to accommodate the object to be dried therein. 300) is separately separated and vibration is generated in the object to be dried placed inside the drying chamber part 300 to provide a vibration-type vacuum drying system in which free moisture acquisition is efficient.

Another object of the present invention is to ventilate the drying chamber unit 300 by being connected to the other ends of the first conduit 410 and the second conduit 420, one end of which communicates with the drying chamber unit 300. A fan 430 and a heating ventilator 400 provided with a heating means 440 provided to warm the outside air sucked by the air fan 430, the first conduit 410 and the second conduit 420 It is connected to the drying chamber unit 300 through the cooling discharge unit 500 provided so that the air discharged from the drying chamber unit 300 is cooled and water is discharged to dry the object to be dried in the drying chamber unit 300 and collect the moisture An object of the present invention is to provide a vibration-type vacuum drying system that collects and conveniently obtains a concentrate.

Another object of the present invention is to proceed in the direction of the vacuum tank 200 from the vacuum pump 100 in the middle position of the first vacuum pipe line 120, and sequentially a vacuum valve 111, a check valve for non-return ( 112) and a filter means 113 are further provided,

The control unit 600 is provided to transmit an ON/OFF control signal to the vacuum valve 111 at a cycle of 1.5 SEC to 2 SEC, and the internal pressure of the vacuum tank 200 is changed at a cycle of 1.5 SEC to 2 SEC to change the vacuum tank It is provided so that the pressing force is changed at a cycle of 1.5 SEC to 2 SEC in the cells of the object to be dried accommodated inside the drying chamber unit 300 in communication with 200, and the non-return check valve 112 has a reverse flow. A backflow information collecting unit 112a is included to transmit backflow generation information to the control unit 600 , and when the backflow information is transmitted to the control unit 600 , the control unit 600 drives the driving motor 110 . A vibration-type vacuum drying system that transmits a control signal to limit is intended to provide

Another object of the present invention is that the internal volume of the vacuum tank 200 and the internal volume of the dry casing 310 are 2.3 to 1 to 2 to 1 to maximize the vacuum effect and 410 and 420, a first induction valve 411 is disposed in the first conduit 410 so that the direction of blowing and discharging to the drying chamber unit 300 is determined according to the selection of the control unit 600, and the second conduit ( A second induction valve 421 is disposed in 420 , and the first pipe line 410 , the cooling discharge unit 500 , and the second pipe line 420 and the cooling discharge unit 500 are connected to a cooling pipe line 510 . ), and an auxiliary induction valve 511 is provided in the cooling pipe 510 to adjust the flow path by turning on/off the cooling pipe 510 to provide a vibration type vacuum drying system that can evenly dry the object to be dried. it is intended to provide

Another object of the present invention is that the cooling discharge unit 500 is provided with a cooling casing 520 in which a cooling medium input hole 521 is disposed on one side, and the cooling introduced from the cooling medium input hole 521 is provided. A cooling medium induction path 522 is provided so that the medium flows inside the cooling casing 520 , and is communicated with the cooling pipe path 510 at the upper center of the cooling casing 520 to the cooling pipe path 510 . An air guideway 523 is provided with a cooling wall 524 interposed between the cooling medium guideway 522 and the cooling medium guideway 522 so as to induce the moisture-accumulated air sucked from the air guideway 523, and is the terminal position of the air guideway 523. It is intended to provide a vibration-type vacuum drying system that is provided with a water discharge hole 525 in the center of the bottom of the cooling casing 520 to facilitate the acquisition of nutrient solution generated from the object to be dried.

On the other hand, the technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly to those of ordinary skill in the art to which the present invention belongs from the description below. can be understood

First, the vibration-type vacuum drying system related to an example of the present invention for realizing the above-described problem may include a vacuum pump 100 provided to be driven by a driving motor 110 .

Here, the vacuum tank 200 communicates with the vacuum pump 100 through the first vacuum tube path 120 to maintain a low-pressure vacuum state therein; may include.

In addition, the vacuum tank 200 and the second vacuum tube passage 210 is closed with a drying casing 310, the drying chamber portion 300 provided as a receiving space 320 so that the object to be dried is accommodated therein; may include

In addition, an air fan 430 for ventilating the drying chamber unit 300 by being connected to the other ends of the first conduit 410 and the second conduit 420, one end of which communicates with the drying chamber unit 300, and the It may include; a heating ventilator 400 provided with a heating means 440 that is provided to heat the outside air that the air fan 430 sucks.

Here, the cooling discharge unit 500 connected to the first conduit 410 and the second conduit 420 and provided so that the moist air discharged from the drying chamber unit 300 is cooled to discharge moisture; may include

In addition, the drive motor 110, the air fan unit 400, and the control unit 600 provided to transmit a control signal to the cooling discharge unit 500; may include.

At this time, in the middle position of the first vacuum pipe line 120, the vacuum pump 100 proceeds in the direction of the vacuum tank 200 and sequentially a vacuum valve 111, a non-return check valve 112 and a filter means ( 113) is further provided, and the vacuum valve 111 is turned ON/OFF according to a signal transmitted by the control unit 600 so that the object to be dried inside the drying casing 310 is turned ON/OFF of the vacuum valve 111 The ON/OFF cycle of the vacuum valve 111 is provided in a range of 1.5 SEC to 2 SEC so as to vibrate according to the operation, and when a reverse flow occurs, the reverse flow generation information is transmitted to the control unit 600 by the non-return check valve 112 . ) includes a backflow information collecting means 112a to transmit it, and when the backflow information is transmitted to the control unit 600, the control unit 600 transmits a control signal to limit the driving of the driving motor 110, , it may be characterized in that it is provided to turn on the pressure regulating valve 330 of the drying chamber part 300 .

On the other hand, it may be characterized in that the internal volume of the vacuum tank 200 and the internal volume of the drying casing 310 are provided in a ratio of 2.3 to 1 to 2 to 1.

Here, the first and second pipelines 410 and 420 have a first induction valve ( 411) is disposed, and a second induction valve 421 is disposed in the second pipe line 420, and a cooling pipe line 510 is provided between the first and second pipe lines 410 and 420 and the cooling discharge unit 500. And, the cooling pipe line 510 may be characterized in that the auxiliary induction valve 511 is provided.

At this time, the cooling discharge unit 500 is provided with a cooling casing 520 in which a cooling medium inlet hole 521 is disposed on one side, and the cooling medium introduced from the cooling medium inlet hole 521 is supplied to the cooling casing ( A cooling medium induction path 522 is provided so as to flow inside the 520, and is communicated with the cooling pipe 510 at the upper center of the cooling casing 520, so that the accumulating air sucked from the cooling pipe 510 is An air guideway 523 is provided with a cooling wall 524 interposed therebetween in parallel with the cooling medium guideway 522, and the cooling casing 520, which is the terminal position of the air guideway 523. It may be characterized in that the water discharge hole 525 is provided at the center of the bottom.

Here, the air induction road 523 and the cooling medium induction road 522 are provided so as to spiral from the top to the bottom inside the cooling casing 520, and at the end of the air induction road 523, the concentration It may be characterized in that the control unit 600 is provided to generate a control signal so as to limit the further enrichment when the detection means 523a is provided and the concentration is higher than the concentration preset in the controller 600 .

On the other hand, a heater 321 and a heat-resistant camera 322 are installed in the accommodation space 320 to warm the accommodation space 320 before the warming ventilator 400 is driven, and the heat-resistant camera 322 is imaged It is provided so that information is output to the external display 610 through the control unit 600 , and the drying chamber unit 300 is provided with a front door 340 so that the object to be dried is put in and out of the receiving space 320 . The bottom and the front door 340 may be characterized in that a rail (not shown) for entering and exiting the object is further provided.

Accordingly, the present invention provides a vibration type vacuum drying system,

First, there is an effect of efficiently extracting the nutrient solution from the dried object while protecting the nutrients of the dried object by drying it at a low temperature.

Second, the vacuum pump 100 provided to be driven by the driving motor 110 and the vacuum tank 200 are communicated with the vacuum pump 100 through the first vacuum pipe line 120 to maintain a low pressure vacuum state therein. And the vacuum tank 200 and the second vacuum tube path 210 are communicated to each other, sealed with a drying casing 310, and a drying chamber part 300 provided as an accommodating space 320 to accommodate the object to be dried is separated separately. Thus, vibration is generated in the object to be dried placed inside the drying chamber part 300, so that free moisture acquisition is efficient.

Third, a second conduit 420 connected to the other end of the first conduit 410 with one end disposed in communication with the upper part of the drying chamber 300 and having one end disposed at the bottom of the first conduit 410 . A heating ventilator ( 400) and the cooling discharge unit 500 connected to the first conduit 410 and the second conduit 420 and provided so that the moist air discharged from the drying chamber unit 300 is cooled and water is discharged. A concentrated solution is conveniently obtained by drying the object to be dried in the drying chamber unit 300 and collecting the collected moisture.

Fourth, in the middle position of the first vacuum pipe line 120, the vacuum pump 100 proceeds in the direction of the vacuum tank 200 and sequentially a vacuum valve 111, a non-return check valve 112 and a filter means ( 113) is further provided, so that the vacuum valve 111 is provided so that the control unit 600 transmits an ON/OFF control signal to the vacuum valve 111 at a cycle of 1.5 SEC to 2 SEC, the inside of the vacuum tank 200 The pressure is changed in a cycle of 1.5 SEC to 2 SEC so that the pressing force is changed in a cycle of 1.5 SEC to 2 SEC in the cells of the object to be dried accommodated in the drying chamber part 300 communicating with the vacuum tank 200, and the counterflow The non-return check valve 112 includes a backflow information collecting means 112a to transmit backflow generation information to the control unit 600 when a backflow occurs, and when the backflow information is transmitted to the control unit 600, the The control unit 600 transmits a control signal to limit the driving of the driving motor 110 and is provided to turn on the pressure adjusting valve 330 of the drying chamber unit 300 according to the type and moisture content of the object to be dried. Drying takes place in a preset sequence.

Fifth, the internal volume of the vacuum tank 200 and the internal volume of the drying casing 310 are provided in a ratio of 2.3 to 1 to 2 to 1 to maximize the vacuum effect, and the first and second pipelines 410 and 420 are the control unit ( 600), a first induction valve 411 is disposed in the first conduit 410, and a second induction valve 411 is disposed in the second conduit 420 so that the direction of blowing and discharging to the drying chamber 300 is determined according to the selection. A valve 421 is disposed, and the first conduit 410 and the cooling discharge unit 500 and the second conduit 420 and the cooling discharge unit 500 are connected by a cooling conduit 510, and the An auxiliary induction valve 511 is provided in the cooling conduit 510 to turn ON/OFF the cooling conduit 510 to adjust the conduit, so that the object to be dried can be evenly dried.

Sixth, the cooling discharge unit 500 is provided with a cooling casing 520 forming an outer shape, a cooling medium inlet hole 521 is disposed on one side of the cooling casing 520, and is introduced from the cooling medium inlet 521 A cooling medium induction path 522 is provided so that the cooling medium to be used flows inside the cooling casing 520 , and is communicated with the cooling pipe 510 at the upper center of the cooling casing 520 to communicate with the cooling pipe path 510 . ), an air induction passage 523 is provided with a cooling wall 524 interposed therebetween in parallel with the cooling medium induction passage 522 so as to induce the moisture-accumulated air sucked from the air induction passage 523, the terminal position of the air induction passage 523 In the center of the bottom of the cooling casing 520, a water discharge hole 525 is provided, so that it is easy to obtain the nutrient solution generated from the object to be dried.

On the other hand, the effects obtainable in the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description. will be able

The following drawings attached to the present specification illustrate a preferred embodiment of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in those drawings It should not be construed as being limited.
1 to 3 are 3D views showing the overall configuration of a vibration-type vacuum drying system according to an embodiment of the present invention.
4 is a 3D view showing a vacuum pump of a vibration type vacuum drying system according to an embodiment of the present invention.
5 is a 3D view showing a vacuum tank of a vibration type vacuum drying system according to an embodiment of the present invention.
6 and 7 are 3D views showing a drying chamber of a vibration-type vacuum drying system according to an exemplary embodiment of the present invention.
8 and 9 are 3D views showing a heating ventilation part of a vibration-type vacuum drying system according to a preferred embodiment of the present invention.
10 to 14 are 3D views showing a cooling discharge unit of a vibration-type vacuum drying system according to a preferred embodiment of the present invention.
15 is a 3D diagram illustrating a control unit of a vibration-type vacuum drying system according to an exemplary embodiment of the present invention.
16 is a view showing a block diagram of a vibration-type vacuum drying system according to an embodiment of the present invention.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are only exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention are It may be implemented in various forms and is not limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention may have various changes and may have various forms, the embodiments will be illustrated in the drawings and described in detail herein. However, this is not intended to limit the embodiments according to the concept of the present invention to specific disclosed forms, and includes all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

1 to 3 are 3D views showing the overall configuration of a vibration-type vacuum drying system according to a preferred embodiment of the present invention, and FIG. 4 is a vacuum pump of the vibration-type vacuum drying system according to a preferred embodiment of the present invention. It is a 3D drawing, and FIG. 5 is a 3D view showing a vacuum tank of a vibration type vacuum drying system according to a preferred embodiment of the present invention, and FIGS. 6 and 7 are a vibration type vacuum drying system according to a preferred embodiment of the present invention. It is a 3D view showing a drying chamber, and FIGS. 8 and 9 are 3D views showing a heating ventilation part of a vibration-type vacuum drying system according to a preferred embodiment of the present invention, and FIGS. 10 to 14 are views according to a preferred embodiment of the present invention It is a 3D diagram showing a cooling discharge unit of a vibration type vacuum drying system, and FIG. 15 is a 3D diagram showing a control unit of a vibration type vacuum drying system according to a preferred embodiment of the present invention, and FIG. 16 is a preferred embodiment of the present invention. It is a diagram showing a block diagram of a vibration-type vacuum drying system according to the present invention.

In the vibration-type vacuum drying system according to an embodiment of the present invention, first, a vacuum pump 100 provided to be driven by a driving motor 110 is provided.

Here, the vacuum tank 200 is provided to communicate with the vacuum pump 100 through the first vacuum tube path 120 to maintain a low-pressure vacuum therein.

At this time, in the middle position of the first vacuum pipe line 120, the vacuum pump 100 proceeds in the direction of the vacuum tank 200 and sequentially a vacuum valve 111, a non-return check valve 112 and a filter means ( 113) is preferably further provided.

Here, in communication with the vacuum tank 200 and the second vacuum tube path 210, the drying chamber part 300 is sealed with a drying casing 310 and provided as an accommodation space 320 to accommodate the object to be dried therein. provided

At this time, it is preferable that the internal volume of the vacuum tank 200 and the internal volume of the drying casing 310 are 2.3 to 1 to 2 to 1.

On the other hand, the second conduit 420 is connected to the other end of the first conduit 410 disposed in communication with one end at the upper portion of the drying chamber 300, and one end is disposed at the bottom of the first conduit 410 . A heating ventilator ( 400) is provided.

In addition, a cooling discharge unit 500 connected to the first conduit 410 and the second conduit 420 and provided to discharge moisture by cooling the moist air discharged from the drying chamber unit 300 is provided. do.

At this time, the moisture-accumulating air means air containing moisture that is discharged through either the first pipe line 410 or the second pipe line 420 after the drying chamber part 300 is dried.

At this time, the cooling discharge unit 500 is provided with a cooling casing 520 forming an outer shape, a cooling medium input hole 521 is disposed on one side of the cooling casing 520, and in the cooling medium input hole 521 A cooling medium induction path 522 is provided so that the incoming cooling medium flows inside the cooling casing 520, and communicates with the cooling pipe path 510 at the upper center of the cooling casing 520 to communicate with the cooling pipe path ( An air induction passage 523 is provided with a cooling wall 524 interposed between the cooling medium induction passage 522 and the cooling medium induction passage 522 so that the moist air sucked from the 510 is guided, and the end of the air induction passage 523 is provided. It is preferable that a water discharge hole 525 is provided at the center of the bottom of the cooling casing 520, which is a location.

In more detail, the vacuum pump 100 is driven to lower the internal pressure of the vacuum tank 200 than atmospheric pressure to communicate with the drying chamber part 300 so that the internal pressure of the drying chamber part 300 is atmospheric pressure. In a lower state, the drying chamber part 300 is heated with the heating ventilation part 400 to dry the drying chamber part 300 inside, the drying object, and collecting the gas generated by drying from the drying object to be generated and cooled. It is configured to extract the nutrient solution contained in the gas generated by the cooling discharge unit 500 to rehydrate.

Here, a control unit 600 provided to transmit a control signal to the driving motor 110 , the heating ventilator 400 , and the cooling exhaust unit 500 is provided.

At this time, it is preferable that the control unit 600 is provided to transmit an ON/OFF control signal to the vacuum valve 111 at a cycle of 1.5 SEC to 2 SEC.

In more detail, the control unit 600 turns on/off the vacuum valve 111 to adjust the internal pressure of the vacuum tank 200, and accordingly, the drying chamber unit ( 300), the internal pressure of the drying casing 310 is changed so that the internal cells of the object to be dried are changed to a vacuum state or normal pressure state according to the 1.5 SEC to 2 SEC cycle of the vacuum tank 200, and the object to be dried It is provided to change the pressure in the cells to promote the smooth drying process.

In addition, the non-return check valve 112 includes a backflow information collecting means 112a to transmit backflow generation information to the control unit 600 when a backflow occurs, and the backflow information is transmitted to the control unit 600 . In this case, the control unit 600 transmits a control signal to limit the driving of the driving motor 110 , and is provided to turn on the pressure control valve 330 of the drying chamber unit 300 .

In addition, the first and second conduits 410 and 420 include the first conduit 410 and the cooling discharge unit ( 500) and the second pipe line 420 and the cooling discharge unit 500 are connected to a cooling pipe line 510, and an auxiliary induction valve 511 is provided to turn the cooling pipe line 510 ON/OFF to adjust the flow path. It is preferable to be provided in the cooling pipe (510).

On the other hand, the air induction road 523 and the cooling medium induction road 522 are provided so as to spiral from the top to the bottom inside the cooling casing 520, and at the end of the air induction road 523, the concentration is sensed. If the means 523a is provided so that the concentration collected from the concentration sensing means 523a is greater than or equal to the concentration preset in the controller 600, the controller 600 controls the drying of the object to be further restricted. It is desirable to generate a signal.

On the other hand, a heater 321 and a heat-resistant camera 322 are installed in the accommodation space 320 to warm the accommodation space 320 before the heating ventilator 400 is driven, and the heat-resistant camera 322 is It is provided so that the imaging information is output to the external display 610 through the control unit 600, the drying chamber unit 300 is provided with a front door 340 so that the object to be dried is put in and out, the accommodation space 320 It is preferable that rails (not shown) for entering and exiting the object to be dried are further provided on the bottom surface of the and the front door 340 .

By using the vibration-type vacuum drying system according to an embodiment of the present invention described above, it is possible to efficiently extract nutrients from the drying object while protecting the nutrients of the drying object by drying the drying object at a low temperature. A vacuum pump 100 provided to be driven by a motor 110 and a vacuum tank 200 provided to maintain a low pressure vacuum state therein by communicating with the vacuum pump 100 through a first vacuum pipe line 120 and the vacuum The tank 200 communicates with the second vacuum tube path 210, is sealed with a drying casing 310, and separates the drying chamber part 300 provided as an accommodating space 320 so that the object to be dried is accommodated therein. Free moisture acquisition is efficient by generating vibrations in the object to be dried placed inside the chamber part 300, and it is connected to the other end of the first conduit 410 having one end in communication with the upper part of the drying chamber part 300, The air fan 430 and the air fan 430 are connected to the other end of the second conduit 420 having one end disposed at the bottom of the first conduit 410 to ventilate the drying chamber unit 300 . The heating vent unit 400 provided as a heating means 440 provided to warm the inhaled air is connected to the first conduit 410 and the second conduit 420, and from the drying chamber unit 300 A concentrated solution is conveniently obtained by drying the object to be dried in the drying chamber unit 300 through the cooling discharge unit 500 provided to discharge moisture by cooling the discharged moist air and collecting the collected moisture, and the first A vacuum valve 111, a non-return check valve 112, and a filter means 113 are sequentially further provided at an intermediate position of the vacuum pipe line 120 in the direction from the vacuum pump 100 to the vacuum tank 200. The vacuum valve 111 is turned ON/OFF according to the signal transmitted by the control unit 600, so that the object to be dried inside the drying casing 310 becomes internal pressure according to the ON/OFF operation of the vacuum valve 111. The ON/OFF cycle of the vacuum valve 111 to be changed is 1. 5 SEC to 2 SEC, and the non-return check valve 112 includes a back flow information collecting means 112a to transmit back flow generation information to the control unit 600 when a back flow occurs, and the control unit 600 ), the control unit 600 transmits a control signal to limit the driving of the driving motor 110 and turns on the pressure control valve 330 of the drying chamber unit 300 Drying is performed in a preset order according to the type and moisture content of the object to be dried, and the internal volume of the vacuum tank 200 and the internal volume of the drying casing 310 are provided in a ratio of 2.3 to 1 to 2 to 1. In order to maximize the vacuum effect and the first and second pipelines 410 and 420 determine the direction of blowing and discharging to the drying chamber part 300 according to the selection of the control unit 600, the first induction in the first pipeline 410 is provided. A valve 411 is disposed, and a second induction valve 421 is disposed in the second pipe line 420, and a cooling pipe line 510 is provided between the first and second pipe lines 410 and 420 and the cooling discharge unit 500. is provided, and an auxiliary induction valve 511 is provided in the cooling pipe line 510 to have the effect of evenly drying the object to be dried.

Above, the present invention has been described through a preferred embodiment, but the above-described embodiment is merely illustrative of the technical idea of the present invention, and various changes are possible without departing from the technical spirit of the present invention. Those of ordinary skill in the art will be able to understand. Therefore, the protection scope of the present invention should be interpreted by the matters described in the claims, not specific embodiments, and all technical ideas within the corresponding scope should be interpreted as being included in the scope of the present invention.

100 ... vacuum pump
110 ... drive motor
120 ... first vacuum tube furnace
111 ... vacuum valve
112 ... non-return check valve
112a ... Countercurrent information collection means
113 ... filter means
200 ... vacuum tank
210 ... second vacuum tube furnace
300 ... drying chamber
310 ... dry casing
320 ... accommodating space
321 ... heater
322 ... heat-resistant imaging means
330 ... pressure regulating valve
400 ... warm ventilation
410 ... the first pipeline
411 ... first induction valve
420 ... second conduit
421 ... 2nd induction valve
430 ... air fan
440 ... heating means
500 ... cooling exhaust
510 ... cooling pipe
511 ... auxiliary induction valve
520 ... cooling casing
521 ... cooling medium inlet hole
522 ... cooling medium induction furnace
523 ... air taxiway
523a ... concentration sensing means
524 ... cooling wall
525 ... water drain hole
600 ... control
610 ... display

Claims (4)

a vacuum pump 100 provided to be driven by a driving motor 110;
a vacuum tank 200 communicating with the vacuum pump 100 through a first vacuum tube path 120 to maintain a low-pressure vacuum state therein;
The vacuum tank 200 communicates with the second vacuum tube path 210, is sealed with a drying casing 310, and the drying chamber part 300 is provided as an accommodation space 320 so that the object to be dried is accommodated therein;
An air fan 430 and the air fan connected to the other ends of the first conduit 410 and the second conduit 420 having one end in communication with the drying chamber unit 300 to ventilate the drying chamber unit 300 (430) a heating ventilator 400 provided with a heating means 440 that is provided to warm the intake outside air;
Cooling discharge provided so that the drying chamber part 300 , the drying object is dried, and the moisture-containing air discharged through either the first pipe line 410 or the second pipe line 420 is cooled to discharge the moisture part 500; and
A control unit 600 provided to transmit a control signal to the driving motor 110, the heating ventilator 400 and the cooling exhaust unit 500; includes;
In the middle position of the first vacuum pipe line 120, the vacuum pump 100 proceeds in the direction of the vacuum tank 200 and sequentially a vacuum valve 111, a check valve 112 and a filter means 113. This is further provided, and the control unit 600 is provided to transmit an ON/OFF control signal to the vacuum valve 111 in a cycle of 1.5 SEC to 2 SEC, and the internal pressure of the vacuum tank 200 is in a cycle of 1.5 SEC to 2 SEC. It is provided so that the pressing force is changed in a cycle of 1.5 SEC to 2 SEC to the cells of the object to be dried, which are changed and accommodated in the drying chamber part 300 communicating with the vacuum tank 200,
The non-return check valve 112 includes a backflow information collecting means 112a to transmit backflow generation information to the control unit 600 when a backflow occurs, and when the backflow information is transmitted to the control unit 600 . , the control unit 600 is provided to transmit a control signal to limit the driving of the driving motor 110,
It is provided to turn on the pressure regulating valve 330 of the drying chamber part 300,
The internal volume of the vacuum tank 200 and the internal volume of the drying casing 310 are provided in a ratio of 2.3 to 1 to 2 to 1,
The first and second conduits 410 and 420 have a first induction valve 411 in the first conduit 410 so that the direction of blowing and discharging to the drying chamber unit 300 is determined according to the selection of the control unit 600 . is disposed and a second induction valve 421 is disposed in the second pipe line 420, the first pipe line 410, the cooling discharge unit 500, and the second pipe line 420 and the cooling discharge unit (500) is arranged connected to the cooling pipe (510),
An auxiliary induction valve (511) is provided in the cooling pipe (510) to turn on/off the cooling pipe (510) to adjust the flow path,
Vibration type vacuum drying system.
The method of claim 1,
The cooling discharge unit 500,
A cooling casing 520 in which a cooling medium input hole 521 is disposed on one side is provided,
A cooling medium induction path 522 is provided so that the cooling medium introduced from the cooling medium inlet 521 flows inside the cooling casing 520,
In the upper center of the cooling casing 520, the air induction passage 523 communicates with the cooling tube passage 510 so that the moisture-accumulated air sucked from the cooling tube passage 510 is induced. It is provided with a cooling wall 524 interposed therebetween,
Characterized in that a water discharge hole 525 is provided at the center of the bottom of the cooling casing 520, which is the terminal position of the air induction road 523,
Vibration type vacuum drying system.
3. The method of claim 2,
The air induction road 523 and the cooling medium induction road 522 are,
It is provided so as to spiral from the top to the bottom inside the cooling casing 520, and a concentration detecting means 523a is provided at the end of the air induction path 523 so that the concentration collected from the concentration detecting means 523a is Characterized in that when the concentration is higher than the concentration preset in the control unit 600, the control unit 600 generates a control signal to limit drying of the object to be dried further,
Vibration type vacuum drying system.
The method of claim 1,
A heater 321 and a heat-resistant camera 322 are installed in the receiving space 320 to warm the receiving space 320 before the warming ventilator 400 is driven,
It is provided so that the imaging information of the heat-resistant camera 322 is output to the external display 610 through the control unit 600,
The drying chamber part 300 is provided with a front door 340 so that the object to be dried enters and exits,
The lower surface of the accommodation space 320 and the front door 340 are characterized in that a rail (not shown) for entering and leaving the object is further provided.
Vibration type vacuum drying system.

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