CN211372950U - LNG vacuum freeze drying system - Google Patents

Abstract

The utility model belongs to the technical field of the LNG cold energy utilizes, concretely relates to LNG vacuum freeze-drying system. The system comprises an LNG cold recovery system and a vacuum freeze drying system; in the LNG cold recovery system, a storage tank is connected with a cold recovery heat exchanger, a gasifier of the cold recovery heat exchanger is connected, and an outlet of the gasifier is communicated with a user pipe network; the vacuum freeze drying system comprises a main body part and a vacuumizing device connected with the main body part; the cold recovery heat exchanger is respectively connected with the vacuum freeze drying system through two pipelines and forms a closed loop; the main body part is internally provided with a refrigerating device and a freeze drying device which are communicated. The system of the utility model utilizes the waste vaporization cold of LNG, improves the added value of food, ensures the quality of products, saves energy, simplifies the operation flow and improves the efficiency; a set of coil pipes is adopted for cold trap and freezing, so that the volume and investment of equipment are reduced, and the method has important significance for realizing economic sustainable development.

Description

LNG vacuum freeze drying system

Technical Field

The utility model belongs to the technical field of the LNG cold energy utilizes, concretely relates to LNG vacuum freeze-drying system.

Background

Liquefied Natural Gas (LNG) receives attention from all countries in the world due to its characteristics of high efficiency, energy conservation, small volume, convenient transportation, cleanness, environmental protection and the like, and becomes an important strategic reserve energy source. A large amount of cold energy is released during LNG gasification, the cold energy is about 830-860 k J/kg, the converted electric energy is about 231kwh/t, and the cold energy can be greatly wasted if the cold energy cannot be effectively utilized. The conventional refrigeration industry is a large consumer, and according to relevant statistics, the electric energy consumed by the existing refrigeration equipment accounts for 15% of the total power generation amount all over the world, so that the LNG cold energy is used for refrigeration, the refrigeration is a large measure for energy conservation and emission reduction, the freeze-drying device has high requirements on the stability and precision of a refrigeration system and needs low temperature, and the LNG cold energy and the vacuum freeze-drying are combined to fully utilize the low-temperature cold energy of the LNG, so that the energy conservation and consumption reduction of the freeze-drying equipment are realized.

At present, the waste cold of LNG vaporization is not well utilized, for example, in fig. 1, LNG is transported from a storage tank to a vaporizer and then is vaporized and then is led to a user pipe network, and a large amount of cold generated in the process is wasted.

In view of the above-mentioned phenomena, it is necessary to develop a device or system capable of effectively recycling the vaporized waste cold of LNG, and since the freeze-drying system needs a low-temperature system for maintenance, the LNG waste cold recycling temperature is lower and is just suitable for the freeze-drying low-temperature system, so if a device for implementing vacuum freeze-drying by using vaporized waste cold of LNG can be developed, not only is the added value of food increased, but also energy is saved, and sustainable development is achieved.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides an LNG vacuum freeze drying system which integrates the functions of recovering and utilizing LNG vaporization waste cold and realizing the vacuum freeze drying of materials;

the utility model also provides a using method of the LNG vacuum freeze drying system;

the utility model provides a LNG vacuum freeze-drying system solves above technical problem through following technical scheme:

an LNG vacuum freeze drying system comprises an LNG cold recovery system and a vacuum freeze drying system;

in the LNG cold recovery system, a storage tank is connected with a cold recovery heat exchanger, the cold recovery heat exchanger is connected with a gasifier, and an outlet of the gasifier is communicated to a user pipe network;

the vacuum freeze drying system comprises a main body part and a vacuumizing device connected with the main body part;

the cold recovery heat exchanger is respectively connected with the vacuum freeze drying system through two pipelines and forms a closed loop;

the main body part is internally provided with a refrigerating device and a freeze drying device which are communicated.

Preferably, the LNG vacuum freeze drying system comprises an LNG cold recovery system and a vacuum freeze drying system;

in the LNG cold recovery system, a storage tank is connected with an inlet I of a first pipeline in a cold recovery heat exchanger, an outlet I of the first pipeline in the cold recovery heat exchanger is connected with a gasifier, and an outlet of the gasifier is communicated to a user pipe network;

the vacuum freeze drying system comprises a main body part and a vacuumizing device connected with the main body part;

an inlet II and an outlet II of a second pipeline in the cold recovery heat exchanger are respectively connected with the vacuum freeze drying system to form a closed loop;

the main body part is internally provided with a refrigerating device and a freeze drying device which are communicated.

Preferably, a refrigerating area and a drying area are provided; the refrigerating area and the drying area are separated by a first baffle plate capable of passing cold;

the refrigerating device is positioned in the refrigerating area and mainly comprises a transverse baffle plate which divides the refrigerating area into an upper refrigerating area and a lower refrigerating area; the refrigeration coil is respectively positioned in the upper refrigeration area and the lower refrigeration area; an inlet and an outlet of the refrigeration coil are respectively connected with an inlet II and an outlet II of a second pipeline in the cold recovery heat exchanger;

a first fan is arranged at one end of the upper refrigeration area far away from the drying area; a second fan is arranged at one end of the lower refrigerating area far away from the drying area;

the freeze drying device is positioned in the drying area and mainly comprises a plurality of layers of baking pans;

the freeze-drying device is connected with a heat source.

The refrigerating coil comprises a refrigerating coil header and a refrigerating coil branch pipe, wherein the outlet and the inlet of the refrigerating coil header are respectively connected with the inlet II and the outlet II of a second pipeline in the cold recovery heat exchanger.

The heat source includes: the electric heating heat conduction oil barrel, a heat conduction oil inlet pipeline and a heat conduction oil outlet pipeline which are connected with the electric heating heat conduction oil barrel, and a multilayer shelf; the shelves are provided with an upper layer of shelves and a lower layer of shelves, a hollow part is arranged between the two layers of shelves, each layer of shelves is communicated with the heat conduction oil inlet pipeline and the heat conduction oil outlet pipeline, and heat conduction oil can flow between the hollow part of each layer of shelves and the heat conduction oil inlet pipeline and the heat conduction oil outlet pipeline;

each layer of shelves is positioned below its corresponding baking pan.

A guide rail type baking pan is respectively and correspondingly arranged above each layer of shelf, and the guide rail type baking pan moves back and forth through a slide rail and wheels;

preferably, guide rail type baking pans are correspondingly arranged above each layer of shelves respectively, all the guide rail type baking pans are connected with a fixed rod, V-shaped wheels are arranged below a base of the fixed rod, reverse V-shaped tracks matched with the V-shaped wheels are arranged below the V-shaped wheels, the V-shaped wheels can slide back and forth on the reverse V-shaped tracks, and track supporting frames are arranged below the V-shaped tracks.

The shape and the size of each layer of shelves are the same;

preferably, each layer of shelves is arranged in parallel; the distances between adjacent shelves are equal;

preferably, each layer of baking pan is the same in shape and size;

preferably, each layer of baking pan is arranged in parallel;

preferably, the distance between adjacent pans is equal.

The main body part is of a tank body structure, and the section of the main body part is approximately oval;

the vacuumizing device is a vacuum pump;

a buffer tank is arranged between the vacuum pump and the vacuum freeze drying system;

preferably, the first baffle is a slit-shaped baffle;

preferably, the first baffle plate is provided with a plurality of vertical strip-shaped slits;

preferably, the first baffle plate is provided with a plurality of vertical strip-shaped slits extending from the top to the bottom of the first baffle plate;

preferably, the first baffle plate is provided with a plurality of vent holes;

preferably, the first baffle is a hollow baffle;

preferably, the first baffle plate is provided with a plurality of vent holes with the same size and shape;

preferably, the first baffle plate is provided with a plurality of vertical hollow rectangular frames;

preferably, the transverse baffle is a solid plate;

preferably, at least one spray device is arranged at the upper top of the refrigeration area, and the spray device is connected with the water pipe.

Preferably, at least one water outlet and a matched valve are arranged at the lower bottom of the refrigerating area;

preferably, a pressure protection device is arranged at the water outlet;

preferably, the upper part and the lower part of one end of the drying area far away from the refrigerating area are respectively provided with a second baffle plate and a third baffle plate;

preferably, the four corners of the main body part are respectively provided with a quick-opening pressing knob;

preferably, a controller is arranged between the buffer tank and the vacuum pump;

preferably, each pipeline is provided with a valve;

preferably, one end of the drying area far away from the refrigerating area is provided with a pressure gauge;

preferably, the drying zone has a viewing window at an end remote from the refrigeration zone.

Preferably, the cold recovery heat exchanger is filled with a coolant, and the coolant is positioned in a space outside the first pipeline and the second pipeline in the cold recovery heat exchanger;

preferably, the coolant is R23; LNG is conveyed in the first pipeline, and a calcium chloride aqueous solution is conveyed in the second pipeline, namely, a space outside the first pipeline and the second pipeline is filled with a refrigerating medium R23;

preferably, the secondary refrigerant after heat exchange is set to be-60 to-50 ℃;

preferably, the second pipeline in the cold recovery heat exchanger is provided with a 29.9 mass percent calcium chloride water solution.

The utility model discloses a principle of system operation mainly is:

(1) LNG vaporization waste cold recovery principle:

LNG from a storage tank enters a gasifier after heat exchange is carried out between the LNG and secondary refrigerant R23 in a heat exchanger through a cold recovery heat exchanger; or the gas enters the gasifier after being buffered by the buffer tank and is sent to a gas supply pipe network after being regulated. The secondary refrigerant in the heat exchanger is high-concentration calcium chloride aqueous solution, wherein the temperature of the secondary refrigerant after heat exchange is set to be about minus 55 ℃, the secondary refrigerant at minus 55 ℃ enters the refrigeration branch pipe for refrigeration after passing through the refrigeration header pipe, and the refrigeration is mainly used for the refrigeration requirements of food freezing and refrigeration areas;

(2) vacuum freeze drying principle:

the freeze-drying process is generally divided into two drying stages, sublimation drying and desorption drying. The sublimation stage is generally at maximum heating power due to the high moisture content, and the stage is terminated when the temperature of the upper portion of the material reaches the temperature of the heating plate. In the analysis drying stage, the sublimation is finished, the vacuum degree is improved to a certain extent, so that the heating power is controlled, namely, the temperature of the heating plate is reduced, the temperature of dry food is ensured to be lower than the maximum allowable temperature, the sublimation and analysis drying time is reasonably set as an important aspect of ensuring the product quality and saving energy by taking the material reaching a set value as a terminal point.

During vacuum freeze drying, the electric heating heat conduction oil in the electric heating heat conduction oil barrel provides a heat source for a drying room to realize dehydration drying of materials. The heat supply is carried out in a mode that an electric heating wire heats heat conduction oil, wherein the heat conduction oil is conveyed to a shelf through a pump, the shelf is provided with a hollow part, and the hollow part is filled with the heat conduction oil and used for realizing heat supply in the sublimation process;

the vacuum pump has the other function that water vapor generated after sublimation and drying in the drying room passes through the refrigeration coil pipe of the cold trap area through the suction function of the vacuum pump, and the water vapor is condensed on the low-temperature coil pipe to realize the capture of the water vapor;

the vacuum is maintained by the suction of a vacuum pump; when a vacuum freeze drying process is finished, the condensed frost layer of the refrigerating coil pipe in the cold trap can be eliminated through water spraying, and the rear cover of the equipment can be opened for natural melting or manual cleaning.

The utility model discloses in, the mode that adopts steam to condense carries out getting rid of steam, and main performance mode is, catches steam through the cold trap in the drying room, and the steam that produces after the sublimation drying passes through the suction effect of vacuum pump, through the regional refrigeration coil pipe of cold trap (freezing the coil pipe), and steam condenses on microthermal coil pipe and realizes the seizure of steam.

Vacuum freeze drying is a drying scheme for dehydrating materials by using the principle of sublimation. After the material is rapidly frozen, the material is heated in a vacuum (lower than the triple point pressure of water) (2-12 pa) environment, frozen ice crystals in the material are directly sublimated under vacuum, and the ice is changed into water vapor to realize dehydration and drying of the material. Therefore, the device can be divided into three processes, namely a material freezing process, a heating sublimation drying process and a water vapor eliminating process, and two basic conditions, namely continuous supply of heat and continuous removal of generated vapor, must be met to maintain continuous sublimation drying.

Through the utility model discloses a structure, ingenious more than two basic condition of having satisfied for vacuum freeze drying can realize.

The beneficial effects of the utility model reside in that:

(1) by adopting the vacuum freeze drying system with the structure of the utility model, the LNG cold energy and the vacuum freeze drying are combined, so that the low-temperature cold energy of the LNG can be fully utilized, and the energy conservation and consumption reduction of the freeze drying equipment can be realized;

(2) the utility model adopts the guide rail type baking pan, which greatly simplifies the operation flow of goods storage and taking in the freeze-drying process and improves the efficiency;

(3) the middle cold trap and the freezing of the utility model adopt a set of coil pipes, thereby reducing the equipment volume and the capital investment and saving the cost;

(4) the utility model discloses system architecture sets up rationally ingenious, has improved the added value of food through freeze-drying device.

Drawings

FIG. 1 is a schematic diagram of an LNG utilization system before improvement;

FIG. 2 is a view showing the connection between a cold recovery heat exchanger and a vacuum freeze-drying system according to example 1;

FIG. 3 is an enlarged schematic view of the refrigerating apparatus and the freeze-drying apparatus in embodiment 1;

FIG. 4 is a schematic diagram showing the overall configuration of the system in embodiment 1;

FIG. 5 is an enlarged schematic view of the freeze-drying apparatus according to example 1;

FIG. 6 is a schematic configuration diagram of a refrigerating apparatus in embodiment 1;

FIG. 7 is a schematic structural view of a first baffle plate in example 1;

in the figure, 101-storage tank, 102-cold recovery heat exchanger, 103-gasifier, 104-user pipe network, 111-first pipe, 112-inlet I, 113 of first pipe-outlet I, 114 of first pipe-second pipe, 115-outlet II of second pipe, 116-inlet II of second pipe, 23-main body part, 201-refrigeration area, 202-refrigeration coil, 203-first baffle, 204-transverse baffle, 205-refrigeration coil branch, 206-refrigeration coil header, 207-inlet of refrigeration coil header, 208-outlet of refrigeration coil header, 209-first fan, 210-second fan, 211-baking pan, 212-shelf, 213-second baffle, 214-quick-opening knob, 215-conduction oil outlet pipe, 216-heat-conducting oil inlet pipeline, 217-spraying device, 218-water outlet, 219-pressure gauge, 220-observation window, 221-fixing rod, 222-V-shaped wheel, 223-reverse V-shaped rail, 224-rail support frame, 301-drying area, 4-buffer tank, 401-electric heating heat-conducting oil barrel, 402-hollow part, 5-vacuum pump, 502-controller and 503-valve.

Detailed Description

The invention will be further described with reference to the accompanying drawings and specific embodiments so that those skilled in the art may better understand the invention, but the invention is not limited thereto.

Example 1

An LNG vacuum freeze drying system comprises an LNG cold recovery system and a vacuum freeze drying system;

in the LNG cold recovery system, a storage tank 101 is connected with an inlet I112 of a first pipeline 111 in a cold recovery heat exchanger 102, an outlet I113 of the first pipeline in the cold recovery heat exchanger 102 is connected with a gasifier 103, and an outlet of the gasifier 103 is communicated with a user pipe network 104;

the vacuum freeze drying system comprises a main body part 23 and a vacuum pump 5 connected with the main body part 23;

an inlet II 116 and an outlet II 115 of a second pipeline 114 in the cold recovery heat exchanger 102 are respectively connected with the vacuum freeze drying system and form a closed loop;

the main body 23 has a refrigerating device and a freeze-drying device communicated with each other.

The main body part 23 is internally provided with a refrigerating area 201 and a drying area 301; the refrigerating area 201 and the drying area 301 are separated by a first baffle 203 (a strip slit type baffle) capable of passing cold;

the refrigeration device is located in the refrigeration zone 201 and mainly comprises a transverse baffle 204 (solid plate) dividing the refrigeration zone 201 into an upper refrigeration zone and a lower refrigeration zone; also included are refrigeration coils 202 located in the upper and lower refrigeration zones, respectively; the refrigeration coil 202 comprises a refrigeration coil header 206 and refrigeration coil branch pipes 205, wherein an inlet 207 and an outlet 208 of the refrigeration coil header 205 are respectively connected with an inlet II 116 and an outlet II 115 of a second pipeline in the cold recovery heat exchanger 102;

a first fan 209 is arranged at one end of the upper refrigerating area 201 far away from the drying area 301; a second fan 210 is arranged at one end of the lower refrigerating area 201 far away from the drying area 301;

the freeze drying device is positioned in the drying area 301, and mainly comprises a multi-layer baking pan 211; the freeze-drying device is connected with a heat source.

The heat source includes: the system comprises an electric heating heat conduction oil drum 401, a heat conduction oil inlet pipeline 216 and a heat conduction oil outlet pipeline 215 which are connected with the electric heating heat conduction oil drum 401, and a multilayer shelf 212; the shelves 212 are provided with double-layer shelves, a hollow part 402 is arranged between the double-layer shelves, the hollow part 402 of each layer of shelves 212 is communicated with the heat conduction oil inlet pipeline 216 and the heat conduction oil outlet pipeline 215, and heat conduction oil can flow between the hollow part 402 of each layer of shelves and the heat conduction oil inlet pipeline 216 and the heat conduction oil outlet pipeline 215;

each tier of shelves 212 is located below its corresponding baking pan 211;

guide rail type baking pans 211 are correspondingly arranged above each layer of shelves 212, all the guide rail type baking pans 211 are connected with a fixed rod 221, V-shaped wheels 222 are arranged below the base of the fixed rod 221, reverse V-shaped rails 223 matched with the V-shaped wheels 222 are arranged below the V-shaped wheels 222, the V-shaped wheels 222 can slide back and forth on the reverse V-shaped rails 223, and rail supporting frames 224 are arranged below the V-shaped rails 223.

The shape and the size of each layer of shelves 212 are the same, the shelves 212 of each layer are arranged in parallel, and the distances between the adjacent shelves 212 are equal;

the guide rail type baking pan 211 and the shelf 212 are arranged, so that materials to be frozen and dried can be conveniently placed in the baking pan 211;

correspondingly, the shape and size of each layer of baking pan 211 are the same; each layer of baking pans 211 is arranged in parallel; the distance between adjacent trays 211 is equal.

The main body part 23 is a tank structure, and the section of the main body part 23 is approximately oval;

the vacuumizing device is a vacuum pump 5; a buffer tank 4 is arranged between the vacuum pump 5 and the vacuum freeze drying system;

at least one spray device 217 is arranged at the upper top of the refrigerating area 201, and the spray device 217 is connected with the water pipe and used for spraying frost under the refrigerating coil 202.

At least one water outlet 218 and a matched valve are arranged at the lower bottom of the refrigerating area 201 and used for discharging water drops condensed at the lower bottom of the refrigerating coil or shower water;

a pressure protection device is arranged at the water outlet 218 in a matching way;

the upper part and the lower part of one end of the drying area 301 far away from the refrigerating area 201 are respectively provided with a second baffle plate 213 and a third baffle plate; the baffle is arranged, so that the cold energy is ensured to be used for drying materials, and the waste of the cold energy is avoided;

the four corners of the main body part 23 are respectively provided with a quick-opening pressing knob 214 for opening the main body part 23 so as to be convenient for replacing or placing materials or cleaning and removing frost layers in the main body part;

a controller 502 is arranged between the buffer tank 4 and the vacuum pump 5;

each pipeline is provided with a valve 503 for controlling the opening or closing of each pipeline;

the end of the drying area 301 far away from the refrigerating area is provided with a pressure gauge 219; an observation window 220 is arranged at one end of the drying area 301 far away from the refrigerating area and used for observing the drying condition of the materials in the drying area.

The utility model discloses a LNG vacuum freeze-drying system who adopts, in specific use, including following step:

(1) LNG from a storage tank enters a gasifier and a buffer tank after exchanging heat with secondary refrigerant R23 in a heat exchanger through an LNG cold recovery heat exchanger, and is sent to a gas supply pipe network after being regulated;

(2) the calcium chloride aqueous solution (the calcium chloride aqueous solution with the mass concentration of 29.9%) in the second pipeline in the cold recovery heat exchanger is set to have the temperature of the secondary refrigerant after heat exchange between-60 ℃ and-50 ℃, wherein the secondary refrigerant calcium chloride aqueous solution with the temperature of between-60 ℃ and-50 ℃ enters the refrigeration branch pipe for refrigeration after passing through the refrigeration coil header at the upper part of the refrigeration area (in the process, LNG is conveyed in the first pipeline, the calcium chloride aqueous solution is conveyed in the second pipeline, namely, the secondary refrigerant R23 is filled in the space outside the first pipeline and the second pipeline);

(3) when the freezing starts, the integral LNG vacuum freeze drying system is firstly sealed, the fan blows the cold energy of the refrigeration branch pipe to the drying area, and the materials on the shelf in the drying area are frozen;

when the materials are completely frozen, starting a vacuum pump at the moment to enable the pressure in the system to be within the range of 2-12pa, and when the pressure of the system meets the requirement, starting a heating device, wherein water in the materials is sublimated from a solid state to a gaseous state under the vacuum pressure;

(4) under the suction action of a vacuum pump, water vapor generated after sublimation in the drying area is gathered on the refrigerating coil pipe at the lower part of the refrigerating area and condensed into a frost layer, so that the water vapor is captured;

(5) removing the condensed frost layer at the refrigerating coil at the lower part of the refrigerating area; water spraying or natural melting or manual cleaning can be adopted.

The electric heating heat conduction oil in the electric heating heat conduction oil barrel 401 provides a heat source for the drying room 301 to achieve dehydration and drying of the materials. Specifically, electric heating heat conduction oil is conveyed to the hollow shelves 402 of each layer from the electric heating heat conduction oil barrel 401 through a pump, so that the shelves 402 are filled with the heat conduction oil and used for realizing heat supply in the sublimation process;

the vacuum pump 5 has another function that the water vapor generated after sublimation and drying in the drying room 301 passes through a refrigeration coil (freezing coil) (202) in the cold trap area through the suction function of the vacuum pump, and the water vapor is condensed on the low-temperature coil to capture the water vapor;

the vacuum is maintained by the suction of the vacuum pump 5; when a vacuum freeze drying process is finished, the condensed frost layer of the refrigerating coil pipe in the cold trap can be eliminated through water spraying, and the rear cover of the equipment can be opened for natural melting or manual cleaning.

By the method and the system, not only is the waste LNG vaporization cold utilized, but also the added value of food is improved by the freeze-drying device, and the method and the system have important significance for energy conservation, environmental protection and economic sustainable development of the freeze-drying unit. This is the biggest innovation point compared with the existing vacuum drying system.

The scope of protection of the present invention is not limited to the above embodiments. A variation commonly used by those skilled in the art, for example, the first baffle 203 has a plurality of vertical strip slits that are staggered with respect to each other; or a plurality of vertical strip-shaped slits extending from the top to the bottom of the first baffle plate are arranged on the first baffle plate 203; alternatively, the first baffle 203 is provided with a plurality of vent holes; or, the first baffle 203 is a hollow baffle; or the first baffle plate 203 is provided with a plurality of vent holes with the same size and shape; or, the first baffle 203 is provided with a plurality of vertical hollow rectangular frames; such a variation is also within the scope of the present invention.

Claims (31)

1. An LNG vacuum freezing and drying system is characterized by comprising an LNG cold recovery system and a vacuum freezing and drying system;

in the LNG cold recovery system, a storage tank (101) is connected with a cold recovery heat exchanger (102), the cold recovery heat exchanger (102) is connected with a gasifier (103), and an outlet of the gasifier (103) is communicated with a user pipe network (104);

the vacuum freeze drying system comprises a main body part (23) and a vacuumizing device connected with the main body part (23);

the cold recovery heat exchanger (102) is respectively connected with the vacuum freeze drying system through two pipelines to form a closed loop;

the main body part (23) is internally provided with a refrigerating device and a freeze drying device which are communicated with each other.

2. An LNG vacuum freeze-drying system according to claim 1, characterized in that the storage tank (101) is connected to an inlet I (112) of a first conduit (111) in the cold recovery heat exchanger (102), and an outlet I (113) of the first conduit in the cold recovery heat exchanger (102) is connected to the vaporizer (103) via a conduit;

an inlet II (116) and an outlet II (115) of a second pipeline (114) in the cold recovery heat exchanger (102) are respectively connected with the vacuum freeze drying system and form a closed loop.

3. An LNG vacuum freeze drying system according to claim 1, characterized in that the main body (23) has a refrigeration zone (201) and a drying zone (301) therein; the refrigerating area (201) and the drying area (301) are separated by a first baffle (203) capable of passing cold;

the refrigeration device is positioned in the refrigeration area (201), and mainly comprises a transverse baffle (204) which divides the refrigeration area (201) into an upper refrigeration area and a lower refrigeration area; also includes refrigeration coils (202) located in the upper and lower refrigeration zones, respectively; an inlet (207) and an outlet (208) of the refrigeration coil (202) are respectively connected with an inlet II (116) and an outlet II (115) of a second pipeline in the cold recovery heat exchanger (102);

a first fan (209) is arranged at one end of the upper refrigerating area (201) far away from the drying area (301); a second fan (210) is arranged at one end of the lower refrigerating area (201) far away from the drying area (301);

the freeze drying device is positioned in the drying area (301), and mainly comprises a multi-layer baking pan (211);

the freeze-drying device is connected with a heat source.

4. An LNG vacuum freeze-drying system according to any of claims 1-3 characterised in that the refrigeration coil (202) comprises a refrigeration coil header (206) and a refrigeration coil branch (205), the inlet (207) and outlet (208) of the refrigeration coil branch (205) being connected to the inlet II (116) and outlet II (115) of the second conduit in the cold recovery heat exchanger (102), respectively.

5. The LNG vacuum freeze-drying system of claim 4, wherein the heat source comprises: the electric heating heat conduction oil barrel (401), a heat conduction oil inlet pipeline (216) and a heat conduction oil outlet pipeline (215) which are connected with the electric heating heat conduction oil barrel (401), and a multilayer shelf (212); the shelves (212) are provided with double layers of shelves, hollow parts (402) are arranged among the shelves, each layer of shelves (212) is communicated with a heat conduction oil inlet pipeline (216) and a heat conduction oil outlet pipeline (215), and heat conduction oil can flow among the hollow parts (402) of each layer of shelves, the heat conduction oil inlet pipeline (216) and the heat conduction oil outlet pipeline (215);

each tier of shelves (212) is located below its corresponding baking pan (211).

6. LNG vacuum freeze-drying system according to claim 5, characterized in that above each layer of shelves (212) there is associated a respective rail-like baking pan (211), the rail-like baking pan (211) being moved back and forth by means of rails and wheels.

7. The LNG vacuum freeze-drying system of claim 6, characterized in that all rail-type baking pans (211) are connected with a fixed rod (221), V-shaped wheels (222) are arranged below the base of the fixed rod (221), a reverse V-shaped track (223) matched with the V-shaped wheels (222) is arranged below the V-shaped wheels (222), the V-shaped wheels (222) can slide back and forth on the reverse V-shaped track (223), and a rail support frame (224) is arranged below the reverse V-shaped track (223).

8. The LNG vacuum freeze-drying system of claim 7, wherein each layer of shelves (212) is identical in shape and size.

9. The LNG vacuum freeze-drying system of claim 7, wherein each layer of shelves (212) is arranged in parallel; the distances between adjacent shelves (212) are equal.

10. An LNG vacuum freeze-drying system according to claim 7, characterized in that the shape and size of each layer of trays (211) are identical.

11. An LNG vacuum freeze-drying system according to claim 7, characterized in that the drying pans (211) of each layer are arranged in parallel.

12. An LNG vacuum freeze-drying system according to claim 7, characterized in that the distance between adjacent trays (211) is equal;

the main body part (23) is of a tank structure, and the cross section of the main body part (23) is approximately oval;

the vacuum pumping device is a vacuum pump (5).

13. An LNG vacuum freeze-drying system according to claim 7, characterized in that there is a buffer tank (4) between the vacuum pump (5) and the vacuum freeze-drying system.

14. LNG vacuum freeze-drying system according to claim 13, characterised in that the first baffle (203) is a slotted baffle.

15. LNG vacuum freeze-drying system according to claim 14, characterized in that the first baffle (203) has a plurality of vertical and parallel strip-shaped slits.

16. The LNG vacuum freeze-drying system according to claim 15, wherein the first baffle (203) has a plurality of vertical elongated slits extending from the top to the bottom of the first baffle (203).

17. The LNG vacuum freeze-drying system according to claim 16, wherein the first baffle (203) has a plurality of vent holes.

18. LNG vacuum freeze-drying system according to claim 17, characterised in that the first baffle (203) is a hollowed-out baffle.

19. The LNG vacuum freeze-drying system according to claim 18, wherein the first baffle (203) has a plurality of vent holes of the same size and shape.

20. The LNG vacuum freeze-drying system of claim 19, wherein the first baffle (203) has a plurality of vertical hollow rectangular frames.

21. LNG vacuum freeze-drying system according to claim 20, characterised in that the transverse baffles (204) are solid plates.

22. LNG vacuum freeze-drying system according to claim 21, characterised in that at least one spray device (217) is provided at the upper top of the refrigeration area (201), the spray device (217) being connected to the water pipe.

23. The LNG vacuum freeze-drying system according to claim 22, wherein the refrigeration zone (201) has at least one drain (218) and associated valve at its lower bottom.

24. The LNG vacuum freeze-drying system according to claim 23, wherein a pressure protection device is provided at the drain port (218).

25. LNG vacuum freeze-drying system according to claim 24, characterised in that the drying zone (301) is provided with a second baffle (213) and a third baffle, respectively, in the upper and lower part of the end remote from the refrigeration zone (201).

26. The LNG vacuum freeze-drying system according to claim 25, wherein the body portion (23) has quick-opening pressing knobs (214) at four corners thereof, respectively.

27. An LNG vacuum freeze-drying system according to claim 26, characterized in that a controller (502) is provided between the buffer tank (4) and the vacuum pump (5).

28. An LNG vacuum freeze-drying system according to claim 27, characterized in that each pipe is provided with a valve (503).

29. LNG vacuum freeze-drying system according to claim 28, characterised in that the drying zone (301) is provided with a pressure gauge (219) at the end remote from the refrigeration zone.

30. An LNG vacuum freeze-drying system according to claim 29, characterized in that the drying zone (301) has a viewing window (220) at the end remote from the refrigeration zone.

31. An LNG vacuum freeze drying system according to claim 30 wherein the cold recovery heat exchanger (102) has coolant therein, the coolant being located in a space outside the first and second conduits of the cold recovery heat exchanger.

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