WO2017086464A1 - 保冷庫、移動体、氷スラリー供給システム、被保冷品輸送システム、被保冷品の保冷方法、被保冷品の輸送方法 - Google Patents
保冷庫、移動体、氷スラリー供給システム、被保冷品輸送システム、被保冷品の保冷方法、被保冷品の輸送方法 Download PDFInfo
- Publication number
- WO2017086464A1 WO2017086464A1 PCT/JP2016/084322 JP2016084322W WO2017086464A1 WO 2017086464 A1 WO2017086464 A1 WO 2017086464A1 JP 2016084322 W JP2016084322 W JP 2016084322W WO 2017086464 A1 WO2017086464 A1 WO 2017086464A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- ice
- cold
- brine
- cold storage
- ice slurry
- Prior art date
Links
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Images
Classifications
-
- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23B—PRESERVING, e.g. BY CANNING, MEAT, FISH, EGGS, FRUIT, VEGETABLES, EDIBLE SEEDS; CHEMICAL RIPENING OF FRUIT OR VEGETABLES; THE PRESERVED, RIPENED, OR CANNED PRODUCTS
- A23B4/00—General methods for preserving meat, sausages, fish or fish products
- A23B4/06—Freezing; Subsequent thawing; Cooling
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
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- F25C1/00—Producing ice
- F25C1/02—Producing natural ice, i.e. without refrigeration
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- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23B—PRESERVING, e.g. BY CANNING, MEAT, FISH, EGGS, FRUIT, VEGETABLES, EDIBLE SEEDS; CHEMICAL RIPENING OF FRUIT OR VEGETABLES; THE PRESERVED, RIPENED, OR CANNED PRODUCTS
- A23B4/00—General methods for preserving meat, sausages, fish or fish products
- A23B4/02—Preserving by means of inorganic salts
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- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23B—PRESERVING, e.g. BY CANNING, MEAT, FISH, EGGS, FRUIT, VEGETABLES, EDIBLE SEEDS; CHEMICAL RIPENING OF FRUIT OR VEGETABLES; THE PRESERVED, RIPENED, OR CANNED PRODUCTS
- A23B4/00—General methods for preserving meat, sausages, fish or fish products
- A23B4/02—Preserving by means of inorganic salts
- A23B4/027—Preserving by means of inorganic salts by inorganic salts other than kitchen salt, or mixtures thereof with organic compounds, e.g. biochemical compounds
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- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23B—PRESERVING, e.g. BY CANNING, MEAT, FISH, EGGS, FRUIT, VEGETABLES, EDIBLE SEEDS; CHEMICAL RIPENING OF FRUIT OR VEGETABLES; THE PRESERVED, RIPENED, OR CANNED PRODUCTS
- A23B4/00—General methods for preserving meat, sausages, fish or fish products
- A23B4/06—Freezing; Subsequent thawing; Cooling
- A23B4/08—Freezing; Subsequent thawing; Cooling with addition of chemicals or treatment with chemicals before or during cooling, e.g. in the form of an ice coating or frozen block
- A23B4/09—Freezing; Subsequent thawing; Cooling with addition of chemicals or treatment with chemicals before or during cooling, e.g. in the form of an ice coating or frozen block with direct contact between the food and the chemical, e.g. liquid N2, at cryogenic temperature
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- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23L—FOODS, FOODSTUFFS, OR NON-ALCOHOLIC BEVERAGES, NOT COVERED BY SUBCLASSES A21D OR A23B-A23J; THEIR PREPARATION OR TREATMENT, e.g. COOKING, MODIFICATION OF NUTRITIVE QUALITIES, PHYSICAL TREATMENT; PRESERVATION OF FOODS OR FOODSTUFFS, IN GENERAL
- A23L3/00—Preservation of foods or foodstuffs, in general, e.g. pasteurising, sterilising, specially adapted for foods or foodstuffs
- A23L3/36—Freezing; Subsequent thawing; Cooling
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- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23L—FOODS, FOODSTUFFS, OR NON-ALCOHOLIC BEVERAGES, NOT COVERED BY SUBCLASSES A21D OR A23B-A23J; THEIR PREPARATION OR TREATMENT, e.g. COOKING, MODIFICATION OF NUTRITIVE QUALITIES, PHYSICAL TREATMENT; PRESERVATION OF FOODS OR FOODSTUFFS, IN GENERAL
- A23L3/00—Preservation of foods or foodstuffs, in general, e.g. pasteurising, sterilising, specially adapted for foods or foodstuffs
- A23L3/36—Freezing; Subsequent thawing; Cooling
- A23L3/37—Freezing; Subsequent thawing; Cooling with addition of or treatment with chemicals
- A23L3/375—Freezing; Subsequent thawing; Cooling with addition of or treatment with chemicals with direct contact between the food and the chemical, e.g. liquid nitrogen, at cryogenic temperature
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- F25B9/00—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point
- F25B9/002—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point characterised by the refrigerant
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
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- F25C1/00—Producing ice
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C1/00—Producing ice
- F25C1/12—Producing ice by freezing water on cooled surfaces, e.g. to form slabs
- F25C1/14—Producing ice by freezing water on cooled surfaces, e.g. to form slabs to form thin sheets which are removed by scraping or wedging, e.g. in the form of flakes
- F25C1/145—Producing ice by freezing water on cooled surfaces, e.g. to form slabs to form thin sheets which are removed by scraping or wedging, e.g. in the form of flakes from the inner walls of cooled bodies
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C5/00—Working or handling ice
- F25C5/02—Apparatus for disintegrating, removing or harvesting ice
- F25C5/04—Apparatus for disintegrating, removing or harvesting ice without the use of saws
- F25C5/12—Ice-shaving machines
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C5/00—Working or handling ice
- F25C5/20—Distributing ice
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C5/00—Working or handling ice
- F25C5/20—Distributing ice
- F25C5/22—Distributing ice particularly adapted for household refrigerators
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D15/00—Devices not covered by group F25D11/00 or F25D13/00, e.g. non-self-contained movable devices
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D3/00—Devices using other cold materials; Devices using cold-storage bodies
- F25D3/02—Devices using other cold materials; Devices using cold-storage bodies using ice, e.g. ice-boxes
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D3/00—Devices using other cold materials; Devices using cold-storage bodies
- F25D3/02—Devices using other cold materials; Devices using cold-storage bodies using ice, e.g. ice-boxes
- F25D3/04—Stationary cabinets
- F25D3/045—Details
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D3/00—Devices using other cold materials; Devices using cold-storage bodies
- F25D3/10—Devices using other cold materials; Devices using cold-storage bodies using liquefied gases, e.g. liquid air
-
- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23V—INDEXING SCHEME RELATING TO FOODS, FOODSTUFFS OR NON-ALCOHOLIC BEVERAGES AND LACTIC OR PROPIONIC ACID BACTERIA USED IN FOODSTUFFS OR FOOD PREPARATION
- A23V2002/00—Food compositions, function of food ingredients or processes for food or foodstuffs
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C2301/00—Special arrangements or features for producing ice
- F25C2301/002—Producing ice slurries
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C2600/00—Control issues
- F25C2600/04—Control means
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A40/00—Adaptation technologies in agriculture, forestry, livestock or agroalimentary production
- Y02A40/90—Adaptation technologies in agriculture, forestry, livestock or agroalimentary production in food processing or handling, e.g. food conservation
- Y02A40/963—Off-grid food refrigeration
Definitions
- the present invention relates to a cold storage, a moving body, an ice slurry supply system, a cooled product transportation system, a cooled product cooling method, and a cooled product transportation method.
- the cooling chamber has a sealed structure so that carbon dioxide generated by sublimation of dry ice does not leak into the luggage compartment, and the through hole provided in the cold container and the packing that seals the storage door are sealed. Carbon dioxide must be discharged into the atmosphere through the gap created by eliminating the lower packing.
- carbon dioxide may fill the cooling chamber, the cooling chamber pressure may increase, and the cooling chamber may be deformed.
- Carbon dioxide is a typical greenhouse gas, and it is not preferable to discharge carbon dioxide generated by sublimation of dry ice to the atmosphere from the viewpoint of global environmental conservation.
- dry ice cannot be recycled, there is also a problem that costs are increased.
- the present invention has been made in view of such circumstances, and an object of the present invention is to provide a cold storage, a moving body, and an ice slurry supply system that have a high cold storage capacity, do not generate carbon dioxide, and can recycle a cold heat source. To do.
- the refrigerator in one aspect of the present invention is: A casing that defines the cold insulation space is a heat insulating structure, and a partition wall that faces the casing is provided at least in the upper part of the cold insulation space, An air slurry between the casing and the partition wall is filled with an ice slurry that is a mixture of flake ice in which brine is frozen and the brine.
- the cold storage according to one aspect of the present invention can include a supply port that supplies the ice slurry to the gap and a discharge port that discharges the ice slurry from the gap.
- an ice slurry storage container filled with the ice slurry can be stored in the gap.
- the casing is a double wall in which a heat insulating material is interposed, and a heat shielding sheet that reflects radiant heat can be attached to a wall surface in contact with the heat insulating material.
- the moving body of one embodiment of the present invention can be equipped with a plurality of cold storages.
- an ice slurry supply facility for supplying the ice slurry to a cool box mounted on a mobile body can be provided at a distribution base.
- the cold article transport system includes: In a cooled product transport system that inserts and transports a cooled product into a cold storage supplied with a coolant containing flake ice frozen in brine, Freezing point adjusting means for adjusting the freezing point of the brine based on the cold temperature required for the cold-insulated product; Flake ice production means for producing the flake ice from the brine having the adjusted freezing point; About the generated flake ice, supply amount adjusting means for adjusting the supply amount to the cold storage, based on the transport time required for the cold object, Is provided.
- the brine is salt water
- the freezing point adjusting means can adjust the freezing point of the brine supplied to the flake ice producing means by adjusting the solute concentration of the brine.
- the freezing point adjusting means can adjust the freezing point of the brine supplied to the flake ice producing means by selecting a predetermined type of brine among the plurality of types.
- the coolant supplied to the cold storage can be an ice slurry that is a mixture of the flake ice and the brine.
- the present invention it is possible to provide a method for realizing a long-time transport of a cold-insulated product by a cool box capable of refrigerating a cold heat source with high cold storage capacity, no generation of carbon dioxide.
- the ice used in the cool box of the present invention is ice (also referred to as flake ice) of a liquid (also referred to as brine) containing an aqueous solution containing a solute that satisfies the following conditions (a) and (b). is there.
- the temperature at the completion of melting is less than 0 ° C.
- the change rate of the solute concentration of the aqueous solution generated from the ice during the melting process is within 30%.
- the ice having a reduced freezing point as described above continues to be stable at a temperature below the freezing point of fresh water when melted, so that the state where cold energy is stored continues. Therefore, the cooling ability of the object to be cooled should be higher than that of ice made of fresh water.
- the present inventors have found that the ice produced by the conventional technique does not have sufficient ability to cool the object to be cooled, for example, the temperature of the ice itself increases rapidly with time.
- the present inventors examined the reason, and even if ice was produced from an aqueous solution containing a solute such as salt in the conventional technique, in practice, ice containing no solute was first produced before the aqueous solution was frozen. As a result, a mixture of ice and solute containing no solute is produced, or only a small amount of ice having a reduced freezing point is produced, so that ice with high cooling capacity is not produced. I found out.
- the present inventors have succeeded in producing liquid ice containing an aqueous solution having a reduced freezing point by a predetermined method (details will be described later).
- the ice used in the cold storage according to the present invention satisfies the above conditions (a) and (b).
- the above conditions (a) and (b) will be described.
- Temporal completion temperature means that the ice used in the refrigerator of the present invention is placed in an environment above the melting point (for example, room temperature and atmospheric pressure) to start melting of the ice, It refers to the temperature of water when it melts into water.
- the temperature at the completion of melting is not particularly limited as long as it is less than 0 ° C., and can be appropriately changed by adjusting the kind and concentration of the solute.
- the temperature at the completion of melting is preferably lower in terms of higher cooling ability, and specifically, -1 ° C or lower (-2 ° C or lower, -3 ° C or lower, -4 ° C or lower, -5 ° C or lower, -6 ° C or lower, -7 ° C or lower, -8 ° C or lower, -9 ° C or lower, -10 ° C or lower, -11 ° C or lower, -12 ° C or lower, -13 ° C or lower, -14 ° C or lower, -15 Or less, ⁇ 16 ° C.
- the temperature at the completion of thawing is not too high.
- -21 ° C or higher (-20 ° C or higher, -19 ° C or higher, -18 ° C or higher, -17 ° C or higher, -16 ° C or higher, -15 ° C or higher, -14 ° C or higher, -13 ° C or higher,- 12 ° C or higher, -11 ° C or higher, -10 ° C or higher, -9 ° C or higher, -8 ° C or higher, -7 ° C or higher, -6 ° C or higher, -5 ° C or higher, -4 ° C or higher, -3 ° C or higher,- 2 ° C or higher, -1 ° C or higher, -0.5 ° C or higher, etc.).
- the ice used in the cool box of the present invention is the rate of change of the solute concentration of the aqueous solution generated from the ice during the melting process (hereinafter referred to as the “rate of change of the solute concentration” in this specification). Is) within 30%. Even in the method described in Patent Document 1, ice having a slightly reduced freezing point may be generated, but most of them are a mixture of water-free ice and solute crystals. Is not enough.
- the ice used in the cool box of the present invention is composed of liquid ice containing an aqueous solution containing a solute, and therefore has a feature that there is little change in the elution rate of the solute during the melting process. Specifically, the change rate of the solute concentration of the aqueous solution generated from ice during the melting process is 30%.
- the “rate of change in the solute concentration of an aqueous solution generated from ice during the melting process” means the ratio of the concentration of the aqueous solution at the completion of melting to the solute concentration in the aqueous solution generated at an arbitrary point in the melting process.
- the “solute concentration” means the concentration of the mass of the solute in the aqueous solution.
- the change rate of the solute concentration in the ice used in the refrigerator of the present invention is not particularly limited as long as it is within 30%, but the smaller the change rate, the higher the purity of the ice of the aqueous solution having a reduced freezing point, that is, This means that the cooling capacity is high.
- the change rate of solute concentration is within 25% (within 24%, within 23%, within 22%, within 21%, within 20%, within 19%, within 18%, within 17%, within 16%. Within 15%, within 14%, within 13%, within 12%, within 11%, within 10%, within 9%, within 8%, within 7%, within 6%, within 5%, within 4%, 3 %, Within 2%, within 1%, within 0.5%, etc.).
- the change rate of the solute concentration is 0.1% or more (0.5% or more, 1% or more, 2% or more, 3% or more, 4% or more, 5% or more, 6% or more, 7% or more, 8 % Or more, 9% or more, 10% or more, 11% or more, 12% or more, 13% or more, 14% or more, 15% or more, 16% or more, 17% or more, 18% or more, 19% or more, 20% or more Etc.).
- solute The type of solute contained in the ice used in the cool box of the present invention is not particularly limited as long as it is a solute when water is used as a solvent, and is appropriately selected according to the desired freezing point, the intended use of the ice to be used, etc. can do.
- the solute include solid solutes and liquid solutes, and typical solid solutes include salts (inorganic salts, organic salts, etc.).
- salts sodium chloride (NaCl) is preferable because it does not excessively lower the temperature of the freezing point and is suitable for cooling fresh animals and plants or a part thereof.
- salt is contained in seawater, it is also preferable in terms of easy procurement.
- ethylene glycol etc. are mentioned as a liquid solute.
- a solute may be contained individually by 1 type and may be contained 2 or more types.
- the concentration of the solute contained in the ice used in the cool box of the present invention is not particularly limited, and can be appropriately selected according to the kind of solute, the desired freezing point, the use of the ice to be used, and the like.
- concentration of the sodium chloride is 0.5% (w / v) or more (1% (w / v) in that the freezing point of the aqueous solution can be further lowered to obtain a high cooling capacity.
- the ice used in the cool box of the present invention is excellent in cooling ability, it is suitable for use as a refrigerant for cooling the object to be cooled.
- the low-temperature refrigerant for cooling the object to be cooled include organic solvents used as an antifreeze liquid such as ethanol in addition to ice, but ice has higher thermal conductivity and higher specific heat than these antifreeze liquids. For this reason, ice having a low freezing point by dissolving a solute such as ice used in the cool box of the present invention is superior in cooling ability to other refrigerants having a temperature lower than 0 ° C. such as antifreeze. Useful.
- the ice used in the cool box of the present invention may or may not contain components other than the above solutes.
- ice refers to a frozen liquid containing an aqueous solution.
- the ice used in the cool box of the present invention continues to be stable at a temperature below the freezing point of fresh water, that is, it can maintain a state where it is not separated for a long time. Therefore, for example, as described later, when the liquid constituting the ice used in the cool box of the present invention is a liquid containing oil in addition to the aqueous solution containing the solute, the oil is uniform. The state lasts for a long time, that is, the state that does not separate can be maintained for a long time.
- the liquid constituting the ice used in the cool box of the present invention may be a liquid containing oil in addition to the aqueous solution containing the solute.
- liquids include raw milk and industrial waste (such as waste milk) containing water and oil.
- waste milk industrial waste
- the liquid is raw milk, it is preferable in terms of improving the functionality when eating the ice.
- the reason why the functionality is improved is that oil (fat) contained in raw milk is confined in ice.
- the ratio of water to oil in the liquid is not particularly limited, and is, for example, 1:99 to 99: 1 (10:90). To 90:10, 20:80 to 80:20, 30:80 to 80:30, 40 to 60:40 to 60, etc.).
- the ice used in the cool box of the present invention may be an aqueous ice containing two or more solutes having different freezing point depression degrees.
- the ice used in the cool box of the present invention may be a mixture of ice of an aqueous solution containing one solute and ice of an aqueous solution containing the other solute.
- ice of an aqueous solution containing sodium chloride as a solute having a different freezing point depression degree from that of ethylene glycol to ice of an aqueous solution containing ethylene glycol as a solute, melting of the ice of the aqueous solution containing ethylene glycol can be delayed. it can.
- dissolved 2 or more types of solutes in the same aqueous solution may be sufficient as the ice used for the cool box of this invention.
- the melting point of the ice in the salt solution can be lowered by using a solute (ethylene glycol, calcium chloride, etc.) that can lower the melting point further than the salt.
- a temperature around -30 ° C that cannot be achieved with ice alone can be achieved.
- the ratio of two or more solutes having different freezing point depression degrees can be appropriately changed according to the purpose.
- This invention includes the refrigerant
- the ice used in the cool box of the present invention is excellent in cooling ability, it is suitable as a refrigerant for cooling the object to be cooled.
- the ice slurry may contain other components of the above ice.
- the ice slurry may contain a mixture of ice and water by containing water in addition to the above ice.
- the solute concentration in ice and the solute concentration in water are preferably close. The reason is as follows.
- the solute concentration of ice When the solute concentration of ice is higher than the solute concentration of water, the temperature of the ice is lower than the saturation freezing point of water, so that water freezes immediately after mixing water with a low solute concentration.
- the solute concentration of ice when the solute concentration of ice is lower than the solute concentration of water, the saturated freeze point of water is lower than the saturated freeze point of ice, so the ice melts and the temperature of the ice slurry consisting of a mixture of ice and water decreases.
- the solute concentrations of the ice and water to be mixed are approximately the same as described above.
- the water may be one obtained by melting the ice, or one prepared separately, but one obtained by melting the ice. It is preferable that
- the ratio of the solute concentration in ice to the solute concentration in water is more preferably 75:25 to 20:80, It is more preferably 70:30 to 30:70, still more preferably 60:40 to 40:60, still more preferably 55:45 to 45:55, and 52:48 to 48: 52 is particularly preferred, and 50:50 is most preferred.
- the ratio of the solute concentration in ice to the solute concentration in water is preferably within the above range.
- Water used as a raw material for ice used in the cold storage of the present invention is not particularly limited, but when using salt as a solute, it is ice of seawater, water obtained by adding salt to seawater, or seawater dilution water. It is preferable. Seawater, water obtained by adding salt to seawater, or seawater-diluted water can be easily procured, thereby reducing costs.
- the ice slurry may further contain a solid having a higher thermal conductivity than that of the ice used in the cold storage according to the present invention, but it is not necessary to contain it.
- a solid having a higher thermal conductivity than that of the ice used in the cold storage according to the present invention, but it is not necessary to contain it.
- the solid When trying to cool an object to be cooled in a short time, it can be achieved by using a solid with high thermal conductivity, but in this case, the solid itself also loses cold energy in a short time and the temperature tends to rise. Not suitable for long-time cooling.
- a solid with high thermal conductivity is suitable for long-time cooling, it is not suitable for cooling an object to be cooled in a short time.
- the ice used in the cool box of the present invention has a high cooling capacity as described above, it is possible to cool for a long time while obtaining a cooling capacity for a short time by a solid having high thermal conductivity.
- solids having higher thermal conductivity than ice used in the refrigerator of the present invention include metals (aluminum, silver, copper, gold, duralumin, antimony, cadmium, zinc, tin, bismuth, tungsten, titanium, iron , Lead, nickel, platinum, magnesium, molybdenum, zirconium, beryllium, indium, niobium, chromium, cobalt, iridium, palladium), alloy (steel (carbon steel, chromium steel, nickel steel, chromium nickel steel, silicon steel, tungsten steel) , Manganese steel, etc.), nickel chromium alloy, aluminum bronze, gunmetal, brass, manganin, silver, constantan, solder, alumel, chromel
- the solid having higher thermal conductivity than ice used in the cold storage of the present invention has a thermal conductivity of 2.3 W / m K or more (3 W / m K or more, 5 W / m K or more, 8 W / m K.
- Etc. preferably a solid having a thermal conductivity of 10 W / m K or more (20 W / m K or more, 30 W / m K or more, 40 W / m K or more, etc.) It is more preferable that it is a solid having a conductivity of 50 W / m K or more (60 W / m K or more, 75 W / m K or more, 90 W / m K or more, etc.), and a thermal conductivity of 100 W / m K or more (125 W / m K or more, 150 W / m K or more, 175 W / m K or more) is more preferable, and the thermal conductivity is 200 W / m K or more (250 W / m K or more, 300 W / m K or more, 350 W / m K or more More preferably, it is a solid having a thermal conductivity of 200 W / m K or higher, and a solid having a thermal conductivity of 400 W
- the total mass of the ice and the liquid containing the aqueous solution used in the cool box of the present invention contained in the slurry is 1 / 100,000 or more (1/50000 or more, 1 / 10,000 or more, 1/5000 or more, 1/1000 or more) 1/500 or more, 1/100 or more, 1/50 or more, 1/10 or more, 1/5 or more, 1/4 or more, 1/3 or more, 1/2 or more, and the like.
- the solid in the present invention may have any shape, but is preferably particulate.
- the solid may be included in a form included in the ice used in the cool box of the present invention, may be included in a form included outside the ice, Since it is easier to directly contact the object to be cooled if it is included in the form of being included outside, the cooling ability is increased. For this reason, it is preferable to be included in a form included outside the ice.
- FIG. 1 is a cross-sectional view showing a configuration of a cold box 1 according to an embodiment of the present invention.
- the cool box 1 includes a casing 4, a cool space 5, a partition wall 6, a heat insulating material 7, and a heat shield sheet 8.
- the casing 4 has a rectangular parallelepiped shape and has a heat insulating structure.
- a partition wall 6 that faces the casing 4 and surrounds the cold insulation space 5 is disposed inside the casing 4.
- the means for making the casing 4 have a heat insulating structure is not particularly limited.
- the cool box 1 has a double wall structure made of steel or FRP (Fiber-Reinforced Plastics / fiber reinforced plastic), and a heat insulating material 7 is interposed in a gap between the double walls. Yes.
- adopted as the heat insulating material 7 is not specifically limited, Specifically, a urethane foam, glass wool, a vacuum heat insulating material etc. are employable, for example.
- the “vacuum heat insulating material” means a heat insulating material in which a porous core material is covered with a laminate film and the inside is reduced in pressure and sealed.
- the cold insulation space 5 is a space for storing an object to be kept cold formed by surrounding the partition wall 6.
- the partition wall 6 is a wall surrounding the cold insulation space 5 and cools the cold insulation space 5 by being cooled by an ice slurry 50 described later.
- the partition wall 6 is preferably made of a material having high thermal conductivity. Specifically, for example, metals such as aluminum and copper can be employed. Thereby, the cold storage space 5 of the cold box 1 can be efficiently cooled.
- a gap 50 is provided between the casing 4 and the partition wall 6.
- the gap 50 is filled with the ice slurry 3. That is, the ice-retaining space 5 can be cooled to the required sub-freezing temperature by filling the gap 50 with the ice slurry 3 using brine capable of maintaining the sub-freezing temperature.
- brine means a liquid containing a liquid heat medium having a low freezing point. Specifically, for example, sodium chloride aqueous solution (brine), calcium chloride aqueous solution, magnesium chloride aqueous solution, ethylene glycol and the like are contained in the brine.
- “Flake ice” means flake (flake) ice in which brine is frozen to a uniform concentration.
- the ice slurry includes a mixture of flake ice obtained by freezing brine and the brine, and includes sherbet-like ice.
- the ice slurry has features such that it can be easily filled into the gap 50 and cooling unevenness is less likely to occur than hard block-shaped ice.
- An ice slurry supply port 40 capable of supplying the ice slurry 3 to the gap 50 is provided at the upper side surface of the casing 4. Further, an ice slurry discharge port 41 through which the ice slurry 3 can be discharged from the gap 50 is provided at the lower side of the casing 4. Further, an open / close valve 42 is provided at the ice slurry supply port 40, and an open / close valve 43 is provided at the ice slurry discharge port 41. Accordingly, the ice slurry can be filled into the gap from the supply port using a pump or the like, and the melted ice slurry can be discharged from the discharge port. Therefore, the cooling capacity of the ice slurry filled in the gap 50 is high. Can be maintained in a state.
- a heat shield sheet 8 for reflecting radiant heat is attached to the inner wall surface in contact with the heat insulating material 7.
- the method to reflect radiant heat is not specifically limited, In this embodiment, the method of sticking the heat shielding sheet 8 is employ
- the heat shield sheet 8 the front side of the aluminum vapor deposition film is reinforced with a film, and on the back side, a heat insulating material such as a woven fabric or a foam sheet is laminated with an adhesive and laminated. Can be used.
- the heat insulation door for carrying in / out a to-be-cooled object is provided in the side part of the cool box 1. As shown in FIG.
- the heat shielding sheet 8 is attached only to the inner wall surface in contact with the heat insulating material 7. However, in addition to the inner wall surface in contact with the heat insulating material 7, the heat insulating sheet 8 is in contact with the heat insulating material 7.
- the heat shield sheet 8 may be adhered to the outer wall surface. Thereby, since radiant heat is reflected using the heat shield sheet stuck on the inner surface of the double wall, heat can be prevented from being transmitted to the cold insulation space.
- FIG. 2 is a cross-sectional view showing the configuration of the cool box 2 according to another embodiment of the present invention. As shown in FIG.
- a plurality of ice slurry storage containers 9 filled with the ice slurry 3 are placed in the gap 50 between the casing 4 and the partition wall 6.
- the shape and material of the ice slurry storage container 9 are not particularly limited, but it is desirable that the ice slurry storage container 9 be formed with a material that can be easily placed in the gap 50 and has high thermal conductivity.
- an ice slurry storage container 9 that is a cylindrical sealed container formed of a metal having high thermal conductivity and that can replace the ice slurry 50 is employed.
- the partition wall 6 is provided with an opening / closing door for storing the ice slurry storage container 9 in the gap 50.
- the wall surface is, for example, an inner wall of a cylindrical structure such as a drum 11 in FIG. 3 to be described later, but is not particularly limited as long as it can be maintained at a temperature below the freezing point of the aqueous solution.
- the temperature of the wall surface is not particularly limited as long as it is maintained at a temperature lower than or equal to the freezing point of the aqueous solution.
- the wall surface temperature is higher than the freezing point of the aqueous solution in that ice having high purity of ice satisfying the above conditions (a) and (b) can be produced.
- the spraying method is not particularly limited, for example, spraying can be performed by spraying from spraying means provided with spraying holes 13a like a spraying unit 13 in FIG. 3 described later.
- the water pressure at the time of injection is, for example, 0.001 MPa or more (0.002 MPa or more, 0.005 MPa or more, 0.01 MPa or more, 0.05 MPa or more, 0.1 MPa or more, 0.2 MPa or more, etc.). 1 MPa or less (0.8 MPa or less, 0.7 MPa or less, 0.6 MPa or less, 0.5 MPa or less, 0.3 MPa or less, 0.1 MPa or less, 0.05 MPa or less, 0.01 MPa or less, etc.) There may be.
- a rotating means such as a rotatable shaft 12 is provided on the central axis of the saddle drum 11, and the spraying is performed by continuous spraying such as spraying while rotating. Also good.
- This invention has the process of collect
- the method of collecting is not particularly limited, and for example, as shown in FIG. 3 to be described later, the ice on the wall surface may be scraped by means such as a blade 15 and the dropped ice may be collected.
- the actual melting completion temperature can be adjusted by adjusting the amount of ice making heat remaining in the ice. In order to adjust the ice making heat, it can be performed by adjusting the holding time of the ice on the wall surface in the recovery step of the present invention.
- FIG. 3 is an image diagram including a partial cross-sectional perspective view showing an outline of the flake ice manufacturing apparatus 10 according to an embodiment of the present invention.
- the flake ice manufacturing apparatus 10 includes a drum 11, a rotating shaft 12, an injection unit 13, a scraping unit 14, a blade 15, a flake ice discharge port 16, and an upper bearing member 17. , A heat protection cover 19, a geared motor 20, a rotary joint 21, a refrigerant clearance 24, a bush 28, a refrigerant supply unit 29, and a rotation control unit 27.
- the drum 11 includes an inner cylinder 22, an outer cylinder 23 surrounding the inner cylinder 22, and a refrigerant clearance 24 formed between the inner cylinder 22 and the outer cylinder 23.
- the outer peripheral surface of the drum 11 is covered with a cylindrical heat-resistant protective cover 19.
- the material of the inner cylinder 22 and the outer cylinder 23 is not particularly limited. In this embodiment, steel is employed.
- Refrigerant is supplied to the refrigerant clearance 24 from the refrigerant supply unit 29 via the refrigerant pipe 35. Thereby, the inner peripheral surface of the inner cylinder 22 is cooled.
- the rotary shaft 12 is arranged on the central axis of the drum 11 and rotates around the material axis with the central shaft as an axis, using a geared motor 20 installed above the upper bearing member 17 as a power source.
- the rotational speed of the geared motor 20 is controlled by a rotation control unit 27 described later.
- a rotary joint 21 is attached to the top of the rotating shaft 12.
- the upper part of the rotating shaft 12 is formed with a hole 12a that extends in the material axis direction and communicates with each pipe 13 (see FIG. 4).
- the injection unit 13 is composed of a plurality of pipes having injection holes 13 a for injecting brine toward the inner peripheral surface of the inner cylinder 22 at the tip, and rotates together with the rotating shaft 12.
- the brine injected from the injection hole 13a adheres to the inner peripheral surface of the inner cylinder 22 cooled by the refrigerant, and freezes rapidly without giving time for separation.
- the plurality of pipes constituting the injection unit 13 extend radially from the rotary shaft 12 in the radial direction of the drum 11.
- the installation height of each pipe is not particularly limited, but in this embodiment, the installation height is set at an upper position of the inner cylinder 22 of the drum 11. Note that a spray nozzle or the like may be employed instead of the pipe.
- the scraping unit 14 is composed of a plurality of arms on which blades 15 that scrape the brine adhering to the inner peripheral surface of the drum 11 in a frozen state are attached to the tip.
- the scraping portion 14 extends in the radial direction of the drum 11 and rotates together with the rotating shaft 12.
- the plurality of arms constituting the scraping portion 14 are mounted so as to be symmetric with respect to the rotating shaft 12.
- the number of arms is not particularly limited, but in the present embodiment, the number of arms is two.
- the size and material of the blade 15 attached to the tip of each arm are not particularly limited as long as the frozen brine can be scraped off.
- the blade 15 in the present embodiment is made of a stainless steel plate having a length substantially equal to the entire length (total height) of the inner cylinder 22, and a plurality of saw teeth 15 a are formed on the end surface facing the inner cylinder 22. .
- the flake ice that has fallen from the flake ice discharge port 16 is stored in a flake ice storage tank 34 (FIG. 4) disposed directly below the flake ice manufacturing apparatus 10.
- the upper bearing member 17 has a shape in which the pan is inverted, and seals the upper surface of the drum 11.
- a bush 24 that supports the rotating shaft 12 is fitted in the center of the upper bearing member 17.
- the rotating shaft 12 is supported only by the upper bearing member 17, and the lower end portion of the rotating shaft 12 is not pivotally supported. That is, since there is no obstacle below the drum 11 when the flake ice scraped by the blade 15 falls, the lower surface of the drum 11 serves as a flake ice discharge port 16 for discharging the flake ice.
- the refrigerant supply unit 29 supplies a refrigerant for cooling the inner peripheral surface of the inner cylinder 22 to the refrigerant clearance 24 via the refrigerant pipe 35.
- the refrigerant supplied by the refrigerant supply unit 29 is not particularly limited as long as it cools the inner peripheral surface of the inner cylinder 22.
- LNG Liquid Natural Gas / liquefied natural gas
- the refrigerant supplied to the refrigerant clearance 24 can be circulated between the refrigerant clearance 24 and the refrigerant supply unit 36 via the refrigerant pipe 35. Thereby, the refrigerant
- the rotation control unit 27 adjusts the rotation speed of the ejection unit 13 and the scraping unit 14 that rotate together with the rotating shaft 12 by adjusting the rotation speed of the geared motor 20.
- the method by which the rotation control unit 27 controls the rotation speed is not particularly limited. Specifically, for example, a control method using an inverter may be employed.
- FIG. 4 is an image diagram showing an overview of the entire flake ice production system 60 including the flake ice production apparatus 10 of FIG.
- the flake ice production system 60 includes a flake ice production apparatus 10, a brine storage tank 30, a pump 31, a brine pipe 32, a brine tank 33, a flake ice storage tank 34, a refrigerant pipe 35, and a freezing point adjustment unit. 36.
- the brine storage tank 30 stores brine as a raw material for flake ice.
- the brine stored in the brine storage tank 30 is fed to the rotary joint 21 via the brine pipe 32 by operating the pump 31, and becomes flake ice by the flake ice manufacturing apparatus 10. That is, the brine fed to the rotary joint 21 is fed to the pit hole 12 a formed in the rotary joint 21 and the rotary shaft 12, and is fed from the pit hole 12 a to each pipe constituting the injection unit 13.
- the brine tank 33 supplies brine to the brine storage tank 30 when the brine in the brine storage tank 30 is low.
- the brine that has flowed down without being frozen on the inner peripheral surface of the inner cylinder 22 is stored in the brine storage tank 30 and is fed again to the rotary joint 21 via the brine pipe 32 by operating the pump 31.
- the flake ice storage tank 34 is disposed immediately below the flake ice manufacturing apparatus 10 and stores the flake ice that has fallen from the flake ice discharge port 16 of the flake ice manufacturing apparatus 10.
- the freezing point adjustment unit 36 adjusts the freezing point of the brine supplied to the brine storage tank 30 by the brine tank 33.
- the freezing point of the salt water varies depending on the concentration, so the freezing point adjustment unit 36 adjusts the concentration of the salt water stored in the brine storage tank 30.
- the method for adjusting the freezing point of the brine is not particularly limited to this.
- the following method can also be employed. That is, a plurality of brine storage tanks 30 are provided, and a plurality of types of brines having different freezing points are stored in each of several brine storage tanks 30.
- the brine freezing point adjustment unit 37 selects a predetermined type of brine based on the required temperature of the flake ice (for example, the required cool temperature for the transported product transported by the flake ice), The flake ice production apparatus 10 is supplied. Thus, the temperature of the flake ice produced can be adjusted by adjusting the freezing point of the brine.
- the refrigerant supply unit 36 supplies the refrigerant to the refrigerant clearance 24 and sets the temperature of the inner peripheral surface of the inner cylinder 22 to be about ⁇ 10 ° C. lower than the freezing point of the salt water. Thereby, the salt water adhering to the inner peripheral surface of the inner cylinder 22 can be frozen.
- the rotation control unit 27 drives the geared motor 20 to rotate the rotating shaft 12 around the material axis.
- the pump 31 supplies brine that is brine into the rotary shaft 12 from the brine storage tank 30 via the rotary joint 21.
- the injection unit 13 that rotates together with the rotating shaft 12 injects salt water toward the inner peripheral surface of the inner peripheral surface of the inner cylinder 22.
- the salt water sprayed from the spray unit 13 comes into contact with the inner peripheral surface of the inner peripheral surface of the inner cylinder 22, it freezes instantly and becomes ice.
- the rotation control unit 27 controls the rotation speed of the rotating shaft 12 to 2 to 4 rpm.
- the rotation control unit 27 controls the rotation speed of the rotary shaft 12 to 10 to 15 rpm.
- the ice generated on the inner peripheral surface of the inner cylinder 22 is scraped off by the scraping unit 14 that rotates together with the rotating shaft 12.
- the ice scraped off by the scraping unit 14 falls from the discharge port 16 as flake ice.
- the flake ice that has fallen from the discharge port 16 is stored in a flake ice storage tank 34 disposed immediately below the flake ice manufacturing apparatus 10.
- the salt water that does not become ice but flows down the inner peripheral surface of the inner cylinder 22 is stored in the brine storage tank 30, and is supplied again to the rotary joint 21 via the brine pipe 32 by operating the pump 31. Is done.
- the brine tank 33 supplies the salt water stored in itself to the brine storage tank 30.
- the rotation control unit 27 can change the temperature of the flake ice manufactured by the flake ice manufacturing apparatus 10 by changing the rotation speed of the geared motor 20.
- salt water is adopted as the brain.
- the freezing point at which salt water freezes depends only on the solute concentration.
- salt water freezes at ⁇ 1.2 ° C. in any case when the applicant adopts salt water as a brain and changes the rotation speed of the rotary shaft 12 using the flake ice production apparatus 10 of the present embodiment, flake ice produced from the same concentration of salt water is obtained.
- the temperature of the liquid crystal changes according to the rotational speed, and in particular, the temperature decreases as the rotational speed decreases.
- the reason for this is that the flake ice is maintained until the ice-heated state is completely melted. Thereby, the temperature of flake ice can be adjusted, fixing the density
- the ice slurry 3 can be manufactured by using a plurality of types of brine prepared in advance as a material so as to correspond to the required cool temperature and cool time.
- the brine is salt water
- the object to be cooled is fresh seafood
- the solute concentration of salt water which is the raw material of ice slurry, is set to be significantly higher than before.
- the theoretical saturation freezing point of salt water having a solute concentration of 13.6% is ⁇ 9.8 ° C.
- the theoretical saturation freezing point of salt water having a solute concentration of 23.1% is ⁇ 21.2 ° C.
- the solute concentration of salt water is less than 13.6%, the freezing rate of fresh seafood by the produced ice slurry 3 becomes slow.
- the solute concentration of the salt water exceeds 23.1%, the salt content is precipitated as crystals, so that the saturation freezing point of the salt water increases.
- the solute concentration of the salt water exceeds 23.1%, the salt content is precipitated as crystals, so that the saturation freezing point of the salt water increases.
- the solute concentrations of the flake ice and the salt water to be mixed for producing the ice slurry are approximately the same (concentration difference within several percent).
- the solute concentration of the flake ice is higher than the solute concentration of the salt water, the temperature of the flake ice is lower than the saturation freezing point of the salt water, so that the water freezes immediately after mixing the salt water having a low solute concentration.
- the solute concentration of the flake ice is lower than the solute concentration of the salt water, the saturation freezing point of the salt water is lower than the saturation freezing point of the flake ice, so that the flake ice melts and the temperature of the ice slurry 3 decreases. Therefore, in order not to fluctuate the state of the ice slurry 3, it is desirable that the solute concentrations of the flake ice and the salt water to be mixed are approximately the same.
- An ice slurry is prepared by mixing with ⁇ 23.1% brine.
- the temperature of the produced ice slurry is ⁇ 9.8 ° C. to ⁇ 21.2 ° C.
- the temperature of the salt water mixed with the manufactured flake ice is set to room temperature or lower. In addition, ice-making efficiency becomes high, so that the temperature of salt water is low.
- the concentration of the brine and the mass ratio of the mixed flake ice and brine are adjusted so that the temperature of the produced ice slurry becomes the required temperature.
- concentration of the brine and the mass ratio of the flake ice and the brine to be mixed it is possible to produce an ice slurry having a plurality of types of temperatures.
- FIG. 5 is an image diagram showing an outline of an ice slurry supply system according to an embodiment of the present invention.
- the cold insulation moving body 44 is a freight train including the cold storage 1.
- the cold moving vehicle 44 is not limited to a freight train, and may be a freight carrying vehicle, a ship, or an aircraft.
- elimination of road congestion caused by not using a car, exhaust gas The effects of reducing CO2 emissions, improving transportation efficiency, saving energy consumption, etc. can be expected by not discharging CO2.
- the ice-retaining space 5 is cooled by filling the gap 50 of the cool box 1 with the ice slurry 3, it is possible to store and transport the object to be cooled in the cold-retaining space 5 without requiring electric power for cooling. .
- greenhouse gases such as carbon dioxide are not generated by sublimation like dry ice. Furthermore, it can be reused as a cold heat source by freezing the melted ice slurry.
- the cool box 1 can freely set the cool temperature independently of the other cool boxes 1, and the temperature of the mounting place is not limited. For this reason, cargoes having different cold storage temperatures (cargoes including a plurality of cold storages 1 with different cold storage temperatures) including normal temperature cargo (freight not using the cold storage 1) can be transferred to one cold storage moving body 44 or It can be mounted on a moving body at room temperature at the same time. Thereby, it can contribute to efficient conveyance of cargo. Further, as described above, since the ice cooler 1 can supply the ice slurry 3 from the ice slurry supply port 40 and discharge the ice slurry 3 from the ice slurry discharge port 41, the ice cooler 1 is provided with an ice slurry supply device 46.
- the ice slurry 3 can be replaced at the physical distribution base 45, and the conveying time can be set freely by changing the amount of the ice slurry 3. This enables long-distance transportation using the distribution base 45 as a relay point.
- the “distribution base” is a distribution hub, and in the present invention, a station, a gas station, a port, an airport, etc., where the cold-reserving moving body 44 such as a freight train, a truck, a ship, an aircraft, etc. stops are collectively referred to. Called “logistics base”.
- the ice slurry 3 is manufactured by the ice slurry supply device 46 at the distribution base 45 including the ice slurry supply device 46.
- the ice slurry 3 produced by the ice slurry supply device 46 is supplied to the cool box 1 by the ice slurry supply control unit 47. That is, the ice slurry 3 produced by the ice slurry supply device 46 is piped from the ice slurry supply port 40 of the cold storage 1 to the cold storage 1 provided in the cold storage moving body 44. Further, the ice slurry 3 that has already been filled in the cool box 1 is recovered by the ice slurry supply device 46 through the ice slurry discharge port 41 of the cool box 1.
- the ice slurry 3 collected by the ice slurry supply device 46 can be reused as a raw material for producing flake ice.
- the ice slurry supply adjusting unit 47 adjusts the type and supply amount of the ice slurry 3 to be supplied to the cool box 1 according to the cool temperature and the cool time of the cool box 1. That is, the temperature of the ice slurry 3 varies depending on the type of flake ice. Therefore, the ice slurry supply adjusting unit 47 selects a suitable type of ice slurry from a plurality of types of ice slurries 3 having different temperatures in accordance with the cold insulation temperature of the cold box 1. Moreover, the suitable filling amount of the ice slurry 3 is adjusted according to the cool time of the cool box 1.
- salt water as a brain
- ice frozen from salt water starts to freeze from the fresh water portion having a high freezing point
- the frozen portion includes a portion where a small amount of salt water is frozen or ice.
- the deposited salt is attached around the ice, and the solute concentration of ice becomes uneven.
- the part that was finally frozen thaws first, and high-concentration salt water comes out, so that the solute concentration in the melted water changes significantly during the melting process, or the temperature goes to 0 ° C. There was a technical problem of rising.
- the solute concentration can be made substantially uniform, and it can be melted from the start of melting.
- the solute concentration and ice temperature are almost constant until the end.
- the quantity of the ice slurry 3 in the cool box 1 can be adjusted, and the time during which the cool temperature in the cool box 1 can be maintained at the required predetermined cool temperature can be adjusted.
- the amount of ice slurry 3 in the cool box is increased, the coolable time can be lengthened, and if the amount of ice slurry 3 in the cool box is decreased, the coolable time can be shortened. .
- the filling amount of the ice slurry 3 can be adjusted in accordance with the transport time of the object to be cooled. Thereby, it becomes possible to efficiently transport the object to be cooled for a long distance under a suitable cold environment.
- the cold storage space 5 is obtained by replacing the ice slurry storage container 9 stored in the cold storage 2 with a new ice slurry storage container 9 at the distribution base 45. Can be maintained in the cold state.
- the cool box 2 selects an ice slurry container 9 suitable for the cool temperature of the cool box 2 from the different types of ice slurry containers 9, and sets the cool time of the cool box 2. Accordingly, the quantity of the ice slurry storage container 9 that is suitable is adjusted. Thereby, it becomes possible to efficiently transport the object to be cooled for a long distance under a suitable cold environment.
- it can also be made to freeze immediately and transport by putting a to-be-cooled goods directly in the ice slurry 3, without using the cold storage 1 or the cold storage 2 mentioned above.
- fresh seafood can be frozen in the ice slurry 3 and then taken out from the ice slurry 3 and stored frozen at or below the temperature at the time of freezing. Thereby, even if it transports to a remote place for a long time, the freshness and taste of fresh seafood do not fall.
- FIG. 6 is a diagram showing an example of a heat insulating structure of the cool box 1 of FIG.
- the casing 4 of the cool box 1 is provided with a double wall outside the heat insulating material 7, and a ventilation clearance 81 is provided between the walls. Air is constantly blown through the blower clearance 81.
- the cool box 1 having a high heat insulating effect can be applied to various fields. Specifically, it can be used for, for example, a refrigerator / freezer, a reefer container, a refrigerator / freezer truck, a cold box, and a cooler box.
- the cool box 1 can be used in every scene.
- the cool box 1 does not require a refrigerator or a generator, brine (salt water) as a refrigerant can be reused, and long distance transportation is also possible due to an excellent heat insulating effect. Furthermore, it can respond to refrigeration transportation, refrigeration transportation, and room temperature transportation, and has the effect of contributing to energy saving and Co2 reduction.
- the heat insulation structure shown in FIG. 6 is applicable also to the cool box 2 of FIG.
- the gap 50 is provided on the inner surface of the casing 4 and filled with the ice slurry 3.
- the gap 50 is provided only on the inner surface (such as the ceiling surface) of the casing,
- the slurry 3 may be filled.
- the shape of the cool box 1 or the cool box 2 is not limited to the rectangular parallelepiped shape as in the above-described embodiment.
- the cold insulation moving body 44 is not limited to a freight train. It may be a moving body such as a vehicle for cargo transportation including an automobile, a ship, and an aircraft.
- the brine is salt water (sodium chloride aqueous solution) in the above-described embodiment, but is not particularly limited.
- an aqueous calcium chloride solution an aqueous magnesium chloride solution, ethylene glycol, or the like can be employed.
- a plurality of types of brines having different freezing points according to differences in solute or concentration can be prepared.
- the ice produced by the ice making apparatus of the present invention is preferably liquid ice containing an aqueous solution containing a solute that satisfies the above conditions (a) and (b). Ice) that does not satisfy one or both of the conditions. That is, the object to be cooled may be kept cold using ice slurries having different solute concentrations of ice and water.
- the solid having a higher thermal conductivity than the ice between the ice contained in the ice slurry and the object to be cooled is preferable to perform cooling so as to intervene. Thereby, it is possible to cool for a long time while obtaining a cooling capability for a short time by a solid having high thermal conductivity. In such a case, another object may be interposed between ice, a solid having a higher thermal conductivity than ice, and an object to be cooled, depending on the purpose.
- the object to be cooled in the ice slurry for example, solid (metal etc.) having a higher thermal conductivity than ice, which is not preferable to contact the object to be cooled from the viewpoint of safety
- the ice slurry is contained, either the ice slurry or the object to be cooled may be accommodated in the bag, and the ice slurry and the object to be cooled may be cooled so as not to be in direct contact with each other.
- the cool box for example, the cool box 1 in FIG. 1 to which the present invention is applied is
- a casing for example, the casing 4 in FIG. 1) that defines the cold insulation space (for example, the cold insulation space 5 in FIG. 1) has a heat insulating structure, and a partition wall (for example, the partition wall 6 in FIG. 1) that faces the casing at least in the upper part of the cold storage space.
- An ice slurry for example, ice slurry 3 in FIG.
- the ice slurry is The solid (for example, metal) which has higher heat conductivity than the said flake ice can be contained. Thereby, cooling capacity can be made high.
- a supply port for supplying the ice slurry to the gap (for example, the ice slurry supply port 40 in FIG. 1) and a discharge port for discharging the ice slurry from the gap (for example, the ice slurry discharge port 41 in FIG. 1) are provided.
- emitted from the ice slurry discharge port 41 by this can be reused as a raw material for manufacturing flake ice.
- An ice slurry storage container (for example, the ice slurry storage container 9 in FIG. 2) filled with the ice slurry can be stored in the gap. Thereby, the cold storage state of the cold storage space 5 can be maintained by exchanging the ice slurry storage container 9 stored in the cold storage 2 with a new ice slurry storage container 9.
- the casing is a double wall in which a heat insulating material (for example, the heat insulating material 7 in FIG. 1) is interposed, and a heat insulating sheet (for example, a heat insulating sheet in FIG. 1) that reflects radiant heat on a wall surface in contact with the heat insulating material. Sheet 8) can be applied.
- a heat insulating material for example, the heat insulating material 7 in FIG. 1
- a heat insulating sheet for example, a heat insulating sheet in FIG. 1 that reflects radiant heat on a wall surface in contact with the heat insulating material.
- Sheet 8 can be applied.
- the mobile body to which the present invention is applied (for example, the cold insulation moving body 44 in FIG. 5) can be equipped with a plurality of cold storages.
- an ice slurry supply system to which the present invention is applied includes an ice slurry supply facility (for example, the ice slurry supply device 46 in FIG. 5) for supplying the ice slurry to a cool box mounted on a mobile body. 5 distribution bases 45).
- an ice slurry supply facility for example, the ice slurry supply device 46 in FIG. 5
- a cool box mounted on a mobile body. 5 distribution bases 45.
- the cooled product transportation system to which the present invention is applied Transporting a cold-insulated product in which the cooled product is inserted and transported in a cool box (for example, the cool box 1 in FIG. 1) in which a coolant (for example, the ice slurry 3 in FIG. 1) containing flake ice frozen in brine is inserted.
- a cool box for example, the cool box 1 in FIG. 1
- a coolant for example, the ice slurry 3 in FIG. 1
- Flake ice production means for example, the flake ice production apparatus 10 in FIG.
- supply amount adjusting means for example, the ice slurry supply adjusting unit 47 in FIG. 5 for adjusting the supply amount to the cold storage, based on the transport time required for the cooled product, Is provided.
- the brine is salt water
- the freezing point adjusting means can adjust the freezing point of the brine supplied to the flake ice producing means by adjusting the solute concentration of the brine.
- the freezing point adjusting means can adjust the freezing point of the brine supplied to the flake ice producing means by selecting a predetermined type of brine among the plurality of types.
- the coolant supplied to the cool box can be an ice slurry (for example, ice slurry 3 in FIG. 1) that is a mixture of the flake ice and the brine.
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Abstract
Description
これに対して、保冷コンテナ(保冷庫)内の上部一端側にドライアイスを収納する冷却室を設け、ドライアイスによって冷却された空気を送風機を介して荷物室内へ吹き出す技術が開示されている(例えば特許文献1参照)。
また、二酸化炭素は代表的な温室効果ガスであり、ドライアイスの昇華により発生する二酸化炭素を大気中に排出することは地球環境保全の観点から好ましいことではない。さらにまた、ドライアイスはリサイクルできないため、コストが掛かるという難点もある。
保冷空間を画成するケーシングが断熱構造とされ、前記保冷空間の少なくとも上部に前記ケーシングと対向する隔壁が設けられ、
前記ケーシングと前記隔壁との間の空隙に、ブラインを凍結させたフレークアイスと前記ブラインとの混合物である氷スラリーが充填されている。
ブラインを凍結させたフレークアイスを含む冷却材が供給された保冷庫に、被保冷品を挿入して輸送する被保冷品輸送システムにおいて、
前記被保冷品に要求される保冷温度に基づいて、前記ブラインの凍結点を調整する凍結点調整手段と、
凍結点が調整された前記ブラインから、前記フレークアイスを製造するフレークアイス製造手段と、
生成された前記フレークアイスについて、前記被保冷品に要求される輸送時間に基づいて、前記保冷庫への供給量を調整する供給量調整手段と、
を備える。
前記凍結点調整手段は、前記塩水の溶質濃度を調整することで、前記フレークアイス製造手段に供給され前記ブラインの凍結点を調整することができる。
前記凍結点調整手段は、前記複数種類のうち所定の種類のブラインを選択することで、前記フレークアイス製造手段に供給される前記ブラインの凍結点を調整することができる。
本発明の保冷庫に使用される氷は、以下の(a)及び(b)の条件を満たす、溶質を含有する水溶液を含む液体(ブラインともいう。)の氷(フレークアイスともいう。)である。
(a)融解完了時の温度が0℃未満である
(b)融解過程で前記氷から発生する水溶液の溶質濃度の変化率が30%以内である
ここで、氷が水に変化するときに必要な熱を「潜熱」というが、この潜熱は温度変化を伴わない。このような潜熱の効果により、上記のような凝固点が低下した氷は、融解時に真水の凝固点以下の温度で安定な状態が続くため、冷熱エネルギーを蓄えた状態が持続することになる。
よって、本来であれば、被冷却物の冷却能が真水からなる氷より高くなるはずである。しかし、従来の技術によって製造された氷は、冷却の際に自身の温度が経時的に早く上がる等、被冷却物を冷却する能力が十分なものではないことを本発明者らは発見した。その理由について本発明者らは検討したところ、従来の技術では食塩等の溶質を含有する水溶液から氷を製造したとしても、実際は、水溶液が凍る前に溶質を含まない氷が先に製造されてしまい、結果として製造されるのは溶質を含まない氷と溶質との混合物となってしまうか、あるいは、凝固点の低下した氷はほんの僅かしか生成されないため、冷却能の高い氷が製造されていなかったことがわかった。
上記(a)に関して、本発明の保冷庫に使用される氷は、溶質を含む水溶液を含む液体の氷であるため、真水(溶質を含まない水)の凝固点より凝固点の温度が低下している。そのため、融解完了時の温度が0℃未満であるという特徴を有する。「融解完了時の温度」とは、本発明の保冷庫に使用される氷を融点以上の環境下(例えば、室温、大気圧下)に置くことで氷の融解を開始させ、全ての氷が融解して水になった時点におけるその水の温度のことを指す。
上記(b)に関して、本発明の保冷庫に使用される氷は、融解過程で氷から発生する水溶液の溶質濃度の変化率(以下、本明細書において「溶質濃度の変化率」と略称する場合がある。)が30%以内であるという特徴を有する。特許文献1に記載されたような方法においても、わずかに凝固点の低下した氷が生じる場合もあるが、そのほとんどは溶質を含まない水の氷と溶質の結晶との混合物であるため、冷却能が十分なものでない。このように溶質を含まない水の氷と溶質の結晶との混合物が多く含まれる場合、氷を融解条件下においた場合、融解に伴う溶質の溶出速度が不安定であり、融解開始時に近い時点である程、溶質が多く溶出し、融解が進むとともに溶質の溶出する量が少なくなり、融解が完了時に近い時点程、溶質の溶出量が少なくなる。これに対し、本発明の保冷庫に使用される氷は、溶質を含む水溶液を含む液体の氷からなるものであるため、融解過程における溶質の溶出速度の変化が少ないという特徴を有する。具体的には、融解過程で氷から発生する水溶液の溶質濃度の変化率が30%である。なお、「融解過程で氷から発生する水溶液の溶質濃度の変化率」とは、融解過程の任意の時点での発生する水溶液における溶質濃度に対する、融解完了時における水溶液の濃度の割合を意味する。なお、「溶質濃度」とは、水溶液中の溶質の質量の濃度を意味する。
本発明の保冷庫に使用される氷に含まれる溶質の種類は、水を溶媒としたときの溶質であれば特に限定されず、所望の凝固点、使用する氷の用途等に応じて、適宜選択することができる。溶質としては、固体状の溶質、液状の溶質等が挙げられるが、代表的な固体状の溶質としては、塩類(無機塩、有機塩等)が挙げられる。特に、塩類のうち、食塩(NaCl)は、凝固点の温度を過度に下げすぎず、生鮮動植物又はその一部の冷却に適してことから好ましい。また、食塩は海水に含まれるものであるため、調達が容易であるという点でも好ましい。また、液状の溶質としては、エチレングリコール等が挙げられる。なお、溶質は1種単独で含まれてもよく、2種以上含まれてもよい。
本発明は、上記の氷を含む、被保冷物を冷却させる冷媒を包含する。上記のとおり、本発明の保冷庫に使用される氷は冷却能に優れるため、被保冷物を冷却させる冷媒に好適である。
図1は、本発明の一実施形態に係る保冷庫1の構成を示す断面図である。
図1に示すように、保冷庫1は、ケーシング4と、保冷空間5と、隔壁6と、断熱材7と、遮熱シート8とを備える。
隔壁6は、保冷空間5を取り囲む壁であり、後述する氷スラリー50によって自らが冷却されることにより保冷空間5を冷却する。隔壁6は、熱伝導率の高い材質で構成されることが望ましい。具体的には、例えばアルミニウム、銅などの金属を採用することができる。これにより、効率良く保冷庫1の保冷空間5を冷却することができる。
ここで、「ブライン」とは、凍結点の低い液体の熱媒体を含む液体を意味する。具体的には、例えば塩化ナトリウム水溶液(塩水)や塩化カルシウム水溶液、塩化マグネシウム水溶液、エチレングリコール等がブラインに含まれる。
また、「フレークアイス」とは、ブラインを濃度が均一になるように凍結させたフレーク(薄片)状の氷を意味する。フレークアイスは比表面積が大きいため、被保冷物を素早く冷却することができる。即ち、ブラインを凍結させたフレークアイスは、融解する際に大量の潜熱を周囲から奪うことができる。また、その間、温度が上昇することもない。従って、長時間に亘って被保冷物を保冷することができる。
また、氷スラリーは、ブラインを凍結させたフレークアイスと、当該ブラインとの混合物を含み、シャーベット状の氷が含まれる。また、氷スラリーは、硬いブロック状の氷に比べて、空隙50への充填が容易であり、また、冷却むらが生じ難い等の特徴を有する。
これにより、ポンプ等を用いて供給口から空隙に氷スラリーを充填すると共に、溶けた氷スラリーを排出口から排出させることができるため、空隙50内に充填されている氷スラリーの冷却能力を高い状態で維持させることができる。
また、図示していないが、保冷庫1の側面部には、被保冷物を搬出入するための断熱扉が設けられている。
なお、本実施形態では、断熱材7と接する内方側の壁面にのみ遮熱シート8を貼着させているが、断熱材7と接する内方側の壁面に加えて、断熱材7と接する外方側の壁面に遮熱シート8を貼着させてもよい。これにより、二重壁の内面に貼着した遮熱シートを用いて輻射熱を反射させるため、保冷空間に熱が伝達しないようにすることができる。
図1の保冷庫1では、空隙50に対し直接氷スラリー3が充填される構成をとったが、特にこれに限定されず、空隙50には、氷スラリー3が充填された氷スラリー格納容器が収納されていてもよい。即ち、ポンプ等を用いて空隙50に氷スラリー3を充填する代わりに、氷スラリー3が充填された複数の氷スラリー格納容器9を空隙50に載置してもよい。
図2は、本発明の他の実施形態に係る保冷庫2の構成を示す断面図である。
図2に示すように、保冷庫2では、ケーシング4と隔壁6との間の空隙50に、氷スラリー3が充填された複数の氷スラリー格納容器9が載置される。
氷スラリー格納容器9の形状及び材質は特に限定されないが、空隙50に載置し易い形状であり、かつ熱伝導率の高い材質で形成されることが望ましい。なお、本実施形態に係る保冷庫2では、熱伝導率の高い金属によって形成された筒状の密閉容器であって、氷スラリー50の入れ替えが可能な氷スラリー格納容器9を採用している。
なお、図示していないが、隔壁6には、氷スラリー格納容器9を空隙50に収納するための開閉扉が設けられている。
容器に溜められた状態の水溶液を含む液体を外部から冷却しても、本発明の保冷庫に使用される氷を製造することはできない。これは、冷却速度が十分でないことに起因すると考えられる。しかしながら、本発明の一実施形態であるフレークアイス製造装置10によれば、溶質を含有する水溶液を含む液体を噴霧することで霧状となった水溶液が凝固点以下の温度に保持された壁面に直接接することにより、従来なかった急速な冷却を可能としている。これにより、上記(a)及び(b)の条件を満たす、冷却能の高い氷を生成することができると考えられる。
本発明は、上述の氷生成工程後に、壁面上において生じた氷を回収する工程を有する。
ドラム11は、内筒22と、内筒22を囲繞する外筒23と、内筒22と外筒23との間に形成される冷媒クリアランス24とで構成される。また、ドラム11の外周面は、円筒状の防熱保護カバー19によって覆われている。内筒22及び外筒23の材質は特に限定されない。なお、本実施形態では鋼が採用されている。
冷媒クリアランス24には、冷媒供給部29から冷媒配管35を介して冷媒が供給される。これにより内筒22の内周面が冷却される。
また、回転軸12の頂部にはロータリージョイント21が取り付けられている。なお、回転軸12の上部には、材軸方向に延在し各パイプ13と連通する竪穴12aが形成されている(図4参照)。
噴射部13を構成する複数のパイプは、回転軸12からドラム11の半径方向に放射状に延出している。各パイプの設置高さは特に限定されないが、本実施形態では、ドラム11の内筒22高さの上部位置に設置されている。なお、パイプに代えてスプレーノズル等を採用してもよい。
掻取部14を構成する複数のアームは、回転軸12に関して対称となるように装着されている。アームの本数は特に限定されないが、本実施形態では、アームの本数を2本としている。各アームの先端部に装着されているブレード15の大きさ及び材質は、特に限定されず、凍結したブラインを掻き取ることができればよい。なお、本実施形態におけるブレード15は、内筒22の全長(全高)に略等しい長さを有するステンレス製の板材からなり、内筒22に面する端面には複数の鋸歯15aが形成されている。
凍結したブラインは、ブレード15によって掻き取られると、フレークアイスとなり、当該フレークアイスは、フレークアイス排出口16から落下する。フレークアイス排出口16から落下したフレークアイスは、フレークアイス製造装置10の直下に配置されたフレークアイス貯留タンク34(図4)内に貯えられる。
即ち、ドラム11の下方には、ブレード15によって掻き取られたフレークアイスが落下する際に障害となる物がないため、ドラム11の下面はフレークアイスを排出するフレークアイス排出口16となる。
冷媒供給部29は、冷媒クリアランス24に対して、内筒22の内周面を冷却させるための冷媒を、冷媒配管35を介して供給する。なお、冷媒供給部29によって供給される冷媒は特に限定されず、内筒22の内周面を冷却させるものであればよい。具体的には例えば、冷媒として、LNG(Liquefied Natural Gas/液化天然ガス)を採用することができる。
本実施形態では、冷媒クリアランス24に供給される冷媒は、冷媒クリアランス24と冷媒供給部36との間を冷媒配管35を介して循環させることができる。これにより、冷媒クリアランス24に供給されている冷媒を冷却機能が高い状態で維持させることができる。
回転制御部27は、ギヤードモータ20の回転速度を調節することにより、回転軸12と共に回転する噴射部13及び掻取部14の回転速度を調節する。なお、回転制御部27が回転速度を制御する手法は特に限定されない。具体的には、例えばインバータによる制御手法を採用してもよい。
図4は、図3のフレークアイス製造装置10を含むフレークアイス製造システム60の全体の概要を示すイメージ図である。
ブライン貯留タンク30は、フレークアイスの原料となるブラインを貯える。ブライン貯留タンク30に貯えられたブラインは、ポンプ31を作動させることによりブライン配管32を介してロータリージョイント21に送給され、フレークアイス製造装置10によってフレークアイスになる。即ち、ロータリージョイント21に送給されたブラインは、ロータリージョイント21及び回転軸12に形成された竪穴12aに送給され、竪穴12aから、噴射部13を構成する各パイプに送給される。
なお、内筒22の内周面で凍結せずに流下したブラインは、ブライン貯留タンク30に貯えられ、ポンプ31を作動させることによりブライン配管32を介してロータリージョイント21に再び送給される。
フレークアイス貯留タンク34は、フレークアイス製造装置10の直下に配置され、フレークアイス製造装置10のフレークアイス排出口16から落下したフレークアイスを貯える。
なお、ブラインの凍結点の調整手法は、特にこれに限定されない。例えば、次のような手法を採用することもできる。
即ち、ブライン貯留タンク30を複数個設け、凍結点が異なる複数種類のブラインを、数個のブライン貯留タンク30の夫々に貯留させる。そして、ブライン凍結点調整部37は、求められるフレークアイスの温度(例えば当該フレークアイスにより搬送される搬送品に対して、求められている保冷温度)に基づいて、所定種類のブラインを選択し、フレークアイス製造装置10に供給する。
このように、ブラインの凍結点を調節することにより、製造されるフレークアイスの温度を調節することができる。
まず、冷媒供給部36は、冷媒クリアランス24に冷媒を供給し、内筒22の内周面の温度を塩水の凍結点より-10℃程度低くなるように設定する。これにより、内筒22の内周面に付着した塩水が凍結させることができる。
内筒22の内周面が冷却されると、回転制御部27は、ギヤードモータ20を駆動させ、回転軸12を材軸周りに回転させる。
回転軸12が回転すると、ポンプ31は、ブライン貯留タンク30からロータリージョイント21を介して回転軸12内にブラインである塩水を供給する。
回転軸内12に塩水が供給されると、回転軸12と共に回転する噴射部13は、内筒22の内周面の内周面に向けて塩水を噴射する。噴射部13から噴射された塩水は、内筒22の内周面の内周面に接触すると瞬時に凍結し氷となる。
このとき、回転制御部27は、回転軸12の回転速度を2~4rpmに制御する。なお、噴射部13の構成要素としてパイプではなくスプレーノズルを使用した場合には、回転制御部27は、回転軸12の回転速度を10~15rpmに制御する。
内筒22の内周面に生成された氷は、回転軸12と共に回転する掻取部14によって掻き取られる。掻取部14によって掻き取られた氷は、フレークアイスとして排出口16から落下する。排出口16から落下したフレークアイスは、フレークアイス製造装置10の直下に配置されたフレークアイス貯留タンク34内に貯えられる。
上述したように、氷とならず、内筒22の内周面を流下した塩水はブライン貯留タンク30に貯えられ、ポンプ31を作動させることによりブライン配管32を介してロータリージョイント21に再び送給される。なお、ブライン貯留タンク30内の塩水が少なくなった場合は、ブラインタンク33が、自身に貯えられている塩水がブライン貯留タンク30に供給する。
例えばブレインとして塩水が採用されているものとする。この場合、塩水が凍結する凍結点は、その溶質濃度のみに依存すると従来から考えられて来た。例えば溶質濃度が0.8%であれば、どんな場合でも-1.2℃で塩水が凍結すると従来から考えられて来た。
しかしながら、本出願人が、ブレインとして塩水を採用して、本実施形態のフレークアイス製造装置10を用いて、回転軸12の回転速度を変化させたところ、同一濃度の塩水から製造されるフレークアイスの温度が、回転数に応じて変化すること、特に回転数が低下すると温度が低下することを発見した。
この理由は、フレークアイスは、製氷熱を帯びた状態が融解し終わるまで維持されるためである。
これにより、ブラインの濃度を、冷蔵、冷凍対象にあわせた所望値に固定しつつ、フレークアイスの温度を調節することができる。
次に、上述したブラインとフレークアイスとを材料とする氷スラリーを製造する手法の一例を説明する。氷スラリー3については、予め用意された複数種類のブラインを材料とすることにより、要求される保冷温度と保冷時間とに対応させたもの製造することができる。
なお、ブラインは塩水であり、被保冷物は生鮮海産物であることとし、また、上述した保冷庫1又は保冷庫2を使用せずに、氷スラリー3の中に直接被保冷物である生鮮海産物を入れることにより瞬間凍結することを想定して説明する。
塩水の溶質濃度が13.6%未満の場合、製造した氷スラリー3による生鮮海産物の凍結速度は遅くなる。一方、塩水の溶質濃度が23.1%を超える場合、塩分が結晶として析出するため、塩水の飽和凍結点が上昇する。
なお、生鮮海産物を直接氷スラリー3に入れた場合、氷スラリーの溶質濃度が高くても、生鮮海産物の表面が瞬間凍結して氷結するため、生鮮海産物中に塩分が侵入することはない。
従って、氷スラリー3の状態を変動させないようにするためには、混合するフレークアイスと塩水の溶質濃度を同程度とすることが望ましい。
本実施形態では、製造された氷スラリーの温度は-9.8℃~-21.2℃となる。製造されたフレークアイスと混合する塩水の温度は、常温もしくはそれを下回る温度とする。なお、塩水の温度が低いほど、製氷効率は高くなる。
このように、ブラインの濃度や、混合するフレークアイスとブラインの質量比を調整することにより、複数種類の温度の氷スラリーを製造することができる。
次に、上述した手法で製造された氷スラリーを保冷庫1に供給する手法、及び保冷庫1を利用した被保冷品の輸送手法について説明する。
図5は、本発明の一実施形態に係る氷スラリー供給システムの概要を示すイメージ図である。
保冷庫1の空隙50に氷スラリー3が充填されることにより保冷空間5が冷却されるため、冷却のための電力を必要とせずに保冷空間5に被保冷物を格納し運搬することができる。また、ドライアイスのように昇華によって二酸化炭素のような温室効果ガスを発生させることもない。さらに、溶けた氷スラリーを凍結させることにより冷熱源として再利用することができる。
さらに、上述した様に、保冷庫1は、氷スラリー供給口40から氷スラリー3を供給させ、氷スラリー排出口41から氷スラリー3を排出することができるため、氷スラリー供給装置46を備える所定の物流拠点45で氷スラリー3の入れ替えを行うことができ、また、氷スラリー3の量を変えることで、搬送時間を自在に設定できる。これにより、物流拠点45を中継地点とした長距離輸送が可能となる。ここで、「物流拠点」は物流のハブであり、本発明では、貨物列車、トラック、船舶、航空機等の保冷移動体44が停車等する、駅、ガソリンスタンド、港、空港等を総称して「物流拠点」と呼ぶ。
即ち、氷スラリー供給装置46で製造された氷スラリー3は、保冷移動体44に備えられている保冷庫1に、保冷庫1の氷スラリー供給口40からパイプ圧送される。また、既に保冷庫1に充填されていた氷スラリー3は、保冷庫1の氷スラリー排出口41を介して氷スラリー供給装置46に回収される。なお、氷スラリー供給装置46によって回収された氷スラリー3は、フレークアイスを製造するための原料として再利用することができる。
即ち、ブレインとして塩水の場合、従来は、塩水を凍らせた氷は、凍結点の高い真水の部分から凍結し始め、最終的に凍結する部分には、少量の塩水が凍結した部分や、氷の周りに析出した塩が付着している状況となり、氷の溶質濃度は不均一となってしまう。そして、融解時には、最終的に凍結した部分が先に融解し、高濃度の塩水が出てくるため、融解水は、融解の過程で溶質濃度が大幅に変化したり、温度が0℃に向けて上昇するといった技術的な課題があった。
しかし、フレークアイス製造装置10によって製造されたフレークアイスは、水と塩とが分離する時間を与えられることなく瞬間凍結されるため、溶質濃度を略均一とすることができ、融解開始から融解し終わるまでの溶質濃度も氷の温度も略一定となる。
これにより、保冷庫1内の氷スラリー3の量を調節し、保冷庫1内の保冷温度を、要求される所定の保冷温度に維持できる時間を調節することができる。具体的には、保冷庫内の氷スラリー3の量が多くすれば保冷可能時間が長くすることができ、保冷庫内の氷スラリー3の量が少なくすれば保冷可能時間が短くすることができる。このため、被保冷物の運搬時間に合わせて氷スラリー3の充填量を調節することができる。
これにより、被保冷物を好適な保冷環境の下、効率良く長距離輸送することが可能となる。
なお、高い断熱効果を有する保冷庫1は、様々な分野に応用が可能である。具体的には、例えば冷蔵・冷凍庫、リーファーコンテナ、冷蔵・冷凍トラック、コールドボックス、クーラーボックスに利用することができる。
また、氷スラリー製造機46をステーション化させることにより、保冷庫1をあらゆる場面で利用できるようにすることもできる。保冷庫1は、冷凍機や発電機を不要とし、冷媒となるブライン(塩水)も再利用が可能であり、また優れた断熱効果によって長距離輸送も可能である。さらに、冷凍輸送、冷蔵輸送、常温輸送に対応することができ、省エネ、Co2削減にも寄与するという効果を有する。
なお、図6に示す断熱構造は、図2の保冷庫2にも適用することができる。
また、保冷庫1又は保冷庫2の形状は、上述した実施例のように直方体形状に限定されない。
また、保冷移動体44は貨物列車に限られない。自動車を含む貨物運搬用の車両、船舶、航空機等の移動体であってもよい。
また、ブラインは、上述した実施形態では塩水(塩化ナトリウム水溶液)としたが、特に限定されない。具体的には、例えば塩化カルシウム水溶液、塩化マグネシウム水溶液、エチレングリコール等を採用することができる。これにより、溶質又は濃度の違いに応じた凍結点の異なる複数種類のブラインを用意することができる。
即ち、本発明が適用される保冷庫(例えば図1の保冷庫1)は、
保冷空間(例えば図1の保冷空間5)を画成するケーシング(例えば図1のケーシング4)が断熱構造とされ、前記保冷空間の少なくとも上部に前記ケーシングと対向する隔壁(例えば図1の隔壁6)が設けられ、
前記ケーシングと前記隔壁との間の空隙(例えば図1の空隙50)に、ブライン(例えば塩水)を凍結させたフレークアイスと前記ブラインとの混合物である氷スラリー(例えば図1の氷スラリー3)が充填される保冷庫である。
これにより、保冷能力が高く、二酸化炭素が発生することがなく、また、冷熱源である氷スラリーを再利用することができる保冷庫を提供することができる。また、被保冷物を遠方まで容易に輸送することができる。
前記フレークアイスより高い熱伝導率を有する固体(例えば金属)を含有することができる。
これにより、冷却能を高くすることができる。
これにより、これにより、氷スラリー排出口41から排出させた氷スラリー3を、フレークアイスを製造するための原料として再利用することができる。
これにより、保冷庫2に収納されている氷スラリー格納容器9を新規な氷スラリー格納容器9と交換することにより保冷空間5の保冷状態を維持させることができる。
ブラインを凍結させたフレークアイスを含む冷却材(例えば図1の氷スラリー3)が挿入された保冷庫(例えば図1の保冷庫1)に、被保冷品を挿入して輸送する被保冷品輸送システムにおいて、
前記被保冷品に要求される保冷温度に基づいて、前記ブラインの凍結点を調整する凍結点調整手段(例えば図4の凍結点調節部36)と、
凍結点が調整された前記ブラインから、前記フレークアイスを生成するフレークアイス製造手段(例えば図3のフレークアイス製造装置10)と、
生成された前記フレークアイスについて、前記被保冷品に要求される輸送時間に基づいて、前記保冷庫への供給量を調整する供給量調整手段(例えば図5の氷スラリー供給調節部47)と、
を備える。
これにより、被保冷物を好適な保冷環境の下、効率良く長距離輸送することが可能となる。
前記凍結点調整手段は、前記塩水の溶質濃度を調整することで、前記フレークアイス製造手段に供給され前記ブラインの凍結点を調整することができる。
前記凍結点調整手段は、前記複数種類のうち所定の種類のブラインを選択することで、前記フレークアイス製造手段に供給される前記ブラインの凍結点を調整することができる。
Claims (13)
- 保冷空間を画成するケーシングが断熱構造とされ、前記保冷空間の少なくとも上部に前記ケーシングと対向する隔壁が設けられ、
前記ケーシングと前記隔壁との間の空隙に、ブラインを凍結させたフレークアイスと前記ブラインとの混合物である氷スラリーが充填される、
保冷庫。 - 前記空隙に前記氷スラリーを供給する供給口と、前記空隙から前記氷スラリーを排出する排出口とを備える、
請求項1に記載の保冷庫。 - 前記空隙には、前記氷スラリーが充填された氷スラリー格納容器が収納される、
請求項1に記載の保冷庫。 - 前記ケーシングは、断熱材が介装された二重壁とされ、前記断熱材と接する壁面に、輻射熱を反射する遮熱シートが貼着されている、
請求項1乃至3のいずれか1項に記載の保冷庫。 - 請求項1乃至4のいずれか1項に記載の保冷庫を複数個搭載可能な、
移動体。 - 請求項5に記載の移動体に搭載される保冷庫に前記氷スラリーを供給する氷スラリー供給設備が物流拠点に配備されている、
氷スラリー供給システム。 - ブラインを凍結させたフレークアイスを含む冷却材が供給された請求項1乃至4のうちいずれか1項に記載の前記保冷庫に、被保冷品を挿入して輸送する被保冷品輸送システムにおいて、
前記被保冷品に要求される保冷温度に基づいて、前記ブラインの凍結点を調整する凍結点調整手段と、
凍結点が調整された前記ブラインから、前記フレークアイスを製造するフレークアイス製造手段と、
生成された前記フレークアイスについて、前記被保冷品に要求される輸送時間に基づいて、前記保冷庫への供給量を調整する供給量調整手段と、
を備える被保冷品輸送システム。 - 前記ブラインは、塩水であり、
前記凍結点調整手段は、前記塩水の溶質濃度を調整することで、前記フレークアイス製造手段に供給され前記ブラインの凍結点を調整する、
請求項7に記載の被保冷品輸送システム。 - 凍結点の異なる複数種類の前記ブラインが用意されており、
前記凍結点調整手段は、前記複数種類のうち所定の種類のブラインを選択することで、前記フレークアイス製造手段に供給される前記ブラインの凍結点を調整する、
請求項7に記載の被保冷品輸送システム。 - 前記保冷庫に供給される前記冷却材は、前記フレークアイスと前記ブラインとの混合物である氷スラリーである、
請求項7乃至9のうちいずれか1項に記載の被保冷品輸送システム。 - 請求項1乃至4のいずれか1項に記載の保冷庫を用いた、被保冷品の保冷方法。
- 請求項5に記載の移動体を用いた、被保冷品の輸送方法。
- 請求項7乃至9のいずれか1項に記載の被保冷品輸送システムを用いた、被保冷品の輸送方法。
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- 2016-11-18 TW TW109132830A patent/TWI747517B/zh active
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JP7153302B2 (ja) | 2018-02-22 | 2022-10-14 | ブランテックインターナショナル株式会社 | フレークアイス製造装置 |
JP2019205366A (ja) * | 2018-05-28 | 2019-12-05 | ブランテック株式会社 | 冷凍装置及び冷凍システム |
JP2019207046A (ja) * | 2018-05-28 | 2019-12-05 | ブランテック株式会社 | 氷スラリー製造装置及び冷凍システム |
JP7148112B2 (ja) | 2018-05-28 | 2022-10-05 | ブランテックインターナショナル株式会社 | 冷凍装置及び冷凍システム |
JP7370555B2 (ja) | 2018-05-28 | 2023-10-30 | ブランテックインターナショナル株式会社 | 氷スラリー製造装置及び冷凍システム |
Also Published As
Publication number | Publication date |
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WO2017086463A1 (ja) | 2017-05-26 |
MY187613A (en) | 2021-10-04 |
TW202110330A (zh) | 2021-03-16 |
CA3004245C (en) | 2022-03-15 |
CA3004245A1 (en) | 2017-05-26 |
WO2017086462A1 (ja) | 2017-05-26 |
WO2017086461A1 (ja) | 2017-05-26 |
TWI747517B (zh) | 2021-11-21 |
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