CZ303202B6 - Insulated container with chargeable cooling module, way of filling the cooling module and use of both the container and the way of filling - Google Patents

Abstract

The present invention relates to an insulated container being provided in the region of its upper wall (2) with an inlet opening (5) communicating with a cooling module (3) supply opening (4) for supplying a cooling medium into the cooling module (3) wherein the cooling module is provided with at least one outlet opening (7) for escape of the cooling medium into the container (1) interior to cool thereof wherein the cooling module (3) inlet opening (5) can be connected with a cooling medium supply device (13). The cooling medium supply device (13) comprises in the region of its end connectable with the cooling module (3) inlet opening (5) magnetic or electromagnetic means, which cooperates with corresponding magnetizable or magnetic means in the region of the container (1) cooling module (3) inlet opening (5) for connecting said cooling medium supply device (13) for delivering the cooling medium into the insulated container (1) or more precisely into the cooling module (3). During filling process, a cooling medium is supplied into a cooling module (3) from above through the inlet opening (5) and the cooling module (3) supply opening (4). Via at least one outlet opening (7), the cooling medium can escape from the cooling module (3) into the interior of the container (1) so as to cool it. In the course of the filling process, a cooling medium supply device (13) is connected through the mediation of a magnetic force with the insulated container (1) or more precisely the cooling module (3). There is proposed the use of the above-described container and storage of temperature-sensitive substances, especially foods, in a cool environment for a time-limited period.

Description

The invention relates to insulated containers with a cooling module, to a method of filling a cooling module of such an isolated container, and to the use of the container and method.

BACKGROUND OF THE INVENTION

For a long time there are known ways to extend the retention time of food or other temperature-sensitive substances against destruction. In particular, can most foods be preserved in processed as well? condition by cooling. Physical, chemical, microbial and enzymatic reactions slow down as temperature decreases.

Therefore, containers with a thermally insulating wall (insulated containers) are used for the transport and storage of perishable goods, in particular foodstuffs. The insulated containers are generally additionally cooled so that the low temperatures inside the insulated container can be maintained for a longer period of time.

Solid or liquefied carbon dioxide or liquefied nitrogen is used to cool the insulated containers. For example, in the Cryogen ^R -Trans process, a liquefied nitrogen stored under the vehicle is sprayed into a storage space in a vacuum-insulated container, and the liquefied nitrogen in the storage space extracts heat energy to cool the temperature-sensitive goods contained therein (Gas aktuell 51, p. 8, Messer Griesheim GmbH, 1996). Cold storage storage plates are also used for cooling purposes, which are filled with a liquid, the so-called "eutectic liquid" or cooling soles.

In the case of cooling modules that are filled with liquefied or snowy carbon dioxide or very low temperature ("deep-cooled") as cooling media, the filling connection sleeve is usually located on the front of the cooling module so that filling is only possible after opening the door isolated container. This has the disadvantage that in each filling process, the cold leaks from the insulated container into the mostly warmer surrounding space. Thereby, each filling process is associated with a loss of cold that can adversely affect the temperature-sensitive substances stored in the insulated container.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an insulated container with a cooling module which, without opening the door of the insulated container, can be reliably and technically simple to fill the cooling module with a cooling medium. It is a further object of the present invention to provide a method of filling a cooling module in an insulated container by which it is possible to introduce the cooling medium into the cooling module in the most efficient and reliable manner without opening the door of the insulated container.

SUMMARY OF THE INVENTION

This object is achieved according to the invention by an insulated container with a cooling module and a coolant supply device, wherein the insulated container comprising a thermal vacuum insulation and formed of stainless steel has a filling opening in the region of its upper wall which communicates with the cooling inlet opening. a module for supplying coolant to the coolant module, the coolant module having at least one outlet opening for escaping coolant into the interior of the container for cooling it, wherein the charge

-1 CZ 303202 B6

Insulated container with refillable cooling module, method of filling the cooling module and use of the container and method

Technical field

The invention relates to insulated containers with a cooling module, to a method of filling a cooling module of such an isolated container, and to the use of the container and method.

BACKGROUND OF THE INVENTION

For a long time there are known ways to extend the retention time of food or other temperature-sensitive substances against destruction. In particular, most foods can be preserved in the processed state by cooling. Physical, chemical, microbial and enzymatic reactions slow down as temperature decreases.

Therefore, containers with a thermally insulating wall (insulated containers) are used for the transport and storage of perishable goods, in particular foodstuffs. The insulated containers are generally additionally cooled so that the low temperatures inside the insulated container can be maintained for a longer period of time.

Solid or liquefied carbon dioxide or liquefied nitrogen is used to cool the insulated containers. For example, in the Cryogen ^R -Trans process, a liquefied nitrogen stored under the vehicle is sprayed into a storage space in a vacuum-insulated container, and the liquefied nitrogen in the storage space extracts heat energy to cool the temperature-sensitive goods contained therein (Gas aktuell 51, p. 8, Messer Griesheim GmbH, 1996). Cold storage storage plates are also used for cooling purposes, which are filled with a liquid, the so-called "eutectic liquid" or cooling soles.

In the case of cooling modules that are filled with liquefied or snowy carbon dioxide or very low temperature ("deep-cooled") as cooling media, the filling connection sleeve is usually located on the front of the cooling module so that filling is only possible after opening the door isolated container. This has the disadvantage that in each filling process, the cold leaks from the insulated container into the mostly warmer surrounding space. Thereby, each filling process is associated with a loss of cold that can adversely affect the temperature-sensitive substances stored in the insulated container.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an insulated container with a cooling module which, without opening the door of the insulated container, can be reliably and technically simple to fill the cooling module with a cooling medium. It is a further object of the present invention to provide a method of filling a cooling module in an insulated container by which it is possible to introduce the cooling medium into the cooling module in the most efficient and reliable manner without opening the door of the insulated container.

SUMMARY OF THE INVENTION

This object is achieved according to the invention by an insulated container with a cooling module and a coolant supply device, wherein the insulated container comprising a thermal vacuum insulation and formed of stainless steel is provided with a filling opening in the region of its upper wall which communicates with the cooling inlet opening. a module for supplying coolant to the coolant module, the coolant module having at least one outlet opening for escaping coolant into the interior of the container for cooling it, wherein the charge

The insulated container opening is connectable to a coolant supply device, and according to the invention, the coolant supply device at the end of the coolant-supplyable end comprises magnetic or electromagnetic means which interact with corresponding magnetizable or magnetic means in the filling area. an opening of an insulated container, for connecting a device for supplying coolant to the insulated container or cooling module, respectively.

The term 'insulated container' (lsolierbehálter) means all conceivable types of at least partially enclosed spaces, such as containers in the narrower sense in the field of the transport of goods (Container), cabinets, towing wagons or semi-trailers or wagons which contain thermally insulating walls; where temperature sensitive products can be stored or transported while maintaining a certain temperature for a certain period of time.

The term "coolant" as used herein refers in particular to a liquefied gas or a very low temperature gas mixture ("deep-cooled gas") which or which at normal ambient temperature (about 23 ° C) and normal pressure (about 1 bar or 0). (1 MPa) is in the form of a gas, such as nitrogen, carbon dioxide or air, and which, or at a corresponding temperature and pressure, is in a liquid, supercritical or solid state, the term "solid" also encompassing lumpy, granular or snow form. .

Preferably, low-temperature liquefied nitrogen (deep-cooled) is used as the cooling medium, the very low-temperature nitrogen being present as a stock in a substantially liquid state, evaporating over time and escaping through the exit port of the cooling module as a gaseous substance into inside the container, thereby cooling it.

According to the invention, the filling opening is sealable by means of closing means which do not protrude beyond the surface of the top wall of the insulated container. For example, an annular permanent magnet may be used as the filler opening, with the insulating material in the center of the filler opening engaging and sealing the passageway through the wall, whereby the annular magnet is held by a steel disc located in the region of the filler opening. It is thus possible to largely prevent cold losses.

It is ensured that at least a portion of the fill opening closure means interact with the means of the device for supplying the coolant to the coolant module to connect the device for supplying coolant to the insulated container or coolant module. In this case, the device for supplying the cooling medium in the region of its end, which can be connected to the filling opening, comprises magnetic or electromagnetic means which cooperate with corresponding magnetizable or magnetic means in the filling opening region of the insulated container for connecting the cooling medium supplying device to the insulated container or cooling module. wherein the connection is preferably accomplished by co-operation in the region of its end connectable to the filling aperture and an annular steel disc which is disposed in the region of the filling aperture. Advantageously, the steel disc may be incorporated in the insulating material of the thermally insulated wall of the insulated container so that no portions protrude from the surface of the top wall of the insulated container.

For example, a coolant injection tube is associated with the coolant supply device, an electromagnetic coil is mounted around the injection tube, and a steel disc is mounted around the feed opening. A magnetic attraction force is applied to the injection tube relative to the insulated container or cooling module, whereby the coolant supply device is coupled to the cooling module. The steel disc is made of a material that is magnetic or magnetically detectable, for example chromium or nickel steel. The injection tube is preferably made of a metallic material, such as copper or stainless steel, and the coolant outlet in the injection tube is appropriately selected according to the required volume flow. The term "injection tube" as used herein refers to any conceivable type of injection device, such as a nozzle, nozzle or injection tube, suitable for introducing a cooling medium into the cooling module. Further, the coolant supply device to the coolant module may comprise a supply line which is connected to a pressurized coolant source.

According to the invention, a coolant supply device is provided to the coolant supply device comprising a shut-off device and a timer coupled to the shut-off device to control the duration of the coolant feed to the cooling module to supply different quantities to the cooling module. cooling medium. As a closing device, for example, a valve or a gate is used. When using an electromagnet in a coolant supply device, for example a steel disc disposed around a charge opening, the coolant supply device is held when power is supplied to the coil, and can be released each time by power interruption, or automatically after the filling process has been completed.

According to the invention, the cooling module is detachably coupled to the insulated container, and comprises devices which are in operative communication with corresponding insulated container devices and allow insertion and storage of the cooling module in the insulated container so that cooling medium can also be supplied to the cooling module outside the insulated container.

According to the invention, it is proposed that the cooling module is made of stainless steel and has thermal vacuum insulation. The vacuum insulation vacuum is preferably below 20 mbar (2 kPa) and particularly preferably 0.001 to 0.1 kPa (0.01 to 1 mbar). In order to improve the thermal insulating properties, a gas filling of the interior space with carbon dioxide or argo25 can be used at said vacuum. According to the invention, the height of the cooling module is 50 to 200 mm, preferably 60 to 100 mm.

According to the invention, at least one cooling module is stored in the insulated container and, next to it, an accumulation plate for cold storage (in short: a cold storage plate). This has the advantage that part of the cooling capacity of the cooling medium can first be received by the cold storage plate. This preferably avoids initial subcooling to cool the goods to be determined. Later, the cold is released again from the cold storage plate, which significantly increases the cooling time. The cold storage plate thus acts as a cooling bumper and storage tank. According to the invention, the cold storage storage plate is stored in an insulated container under the cooling module. The cold storage plate thus preferably acts as a buffer against the too strong cooling effect of the underside of the cooling module. According to the invention, a eutectic liquid is used as the liquid in the cold storage plate. According to the invention, the eutectic liquid has a freezing point of from 0 to -40 ° C, particularly preferably from about -2 to -4 ° C.

The cooling module has an outlet opening from which a substantially coolant medium can escape into the interior of the container, the outlet opening of the cooling module preferably being simultaneously an inlet opening. Advantageously, the opening may be provided with a flap which can be kept closed by its own weight due to gravity or by means of a suitable closing mechanism and can only be opened at a certain pressure of the gaseous cooling medium forming inside the cooling module.

The storage volume of the cooling module for the coolant corresponds to the weight of the coolant to be used, up to 20,000 g, preferably 500 to 15,000 g. Advantageously, varying amounts of coolant can be filled into the cooling module. The amount of refrigerant to be filled depends on a number of parameters, such as the external temperature, the temperature to be kept in the insulated container, the initial temperature in the insulated container, the type of product stored in the insulated container, refrigeration time, transport method and / or type and size of insulated container . For example, very large quantities may be required for shipping tanks and isolated ones

Only relatively small amounts (up to several grams) of coolants may be required for vaccine containers or for certain containers.

According to the invention, the wall of the insulated container, positioned substantially vertically, is formed on its inner surface such that, for example, through a certain lamellar surface structure, the gaseous cooling medium formed in the upper region of the insulated container better falls or flows into the lower region of the insulated container. This can advantageously improve the temperature distribution within the insulated container.

The object of the invention is further solved by a method of filling a cooling module in an insulated container with a cooling medium, wherein the cooling medium is fed to the cooling module from above through a filling port in the top wall of the insulated container and a cooling module inlet opening communicating with said opening. Allows the cooling module to escape through the at least one outlet opening into the interior of the insulated container for cooling, wherein during the filling operation a cooling medium supply device is connected to the insulated container or the cooling module, the method according to the invention being characterized in magnetic force.

Preferably, the magnetic force is exerted by means of an electromagnet in the region of the end of the coolant supply device, the waveguide connection with the filling opening, and by means of a steel disc disposed in the region of the filling opening.

Preferably 200 to 2000 g of coolant per hour, in particular 800 to 1200 g of coolant per hour are evaporated to cool the interior of the insulated container.

According to the invention, the duration of the supply of the cooling medium to the cooling module is controlled by a control device associated with the filling device by introducing a different amount of cooling medium into the cooling module and adjusting the time-required storage of the substances stored inside the insulated container. in the cold, i.e. the storage of the substances in the cold for the desired time within the insulated container is set. Thus, by controlling the filling time, at a given coolant pressure during the filling process, different amounts of coolant can be fed into the cooling module, and the substances stored in the insulated container can be kept refrigerated for the desired period of time. For certain applications, it is advantageous and equally possible to use the coolant pressure control to control the amount of coolant supplied.

Liquefied nitrogen of very low temperature (deep-cooled liquefied nitrogen) is preferably used as the cooling medium.

The insulated container and method are preferably used to keep temperature-sensitive substances refrigerated for a limited period of time, preferably for cooling food.

In addition, the products and the process according to the invention can be precooled and / or pre-frozen. This makes it advantageous to use for storing fresh products for protection against oxidation and for prolonging the shelf life of fresh goods.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of an insulated container with a cooling module; FIG. 2 is a cross-sectional view of an upper portion of an insulated container in a cooling module with an insulated container closure; a section through the upper part of the insulated container and a part of the device for supplying the cold to the cooling module connectable to the insulated container.

-4GB 303202 B6

DETAILED DESCRIPTION OF THE INVENTION

The insulated container I shown in FIG. 1 comprises heat insulating walls 2. Inside the insulated container I is a cooling module 3. The cooling module 3 has an inlet opening 4 which communicates with the filling opening 5 of the insulated container 1. 1 of the insulating wall 2 is provided with a depression 6 and the cooling module 3 is provided with a cooling medium outlet 7.

In FIG. 2, the closure of the insulated container 1 is shown in more detail. In the area of the filling opening 5 of the insulated container 1 is a recess 6 with an annular steel disk 8 inserted therein. An annular permanent magnet 9 may be used as the closure of the filling opening 5, for example, in the center of which the insulating material 10 is disposed so that it extends into the wall passage of the filling opening and forms a seal there. . The wall passage 11 may be formed as a pipe connecting with its end to the outer wall 12 of the cooling module 3. The steel disk is made of a magnetic or magnetizable material, for example chrome or nickel steel.

FIG. 3 shows a device for supplying coolant to the cooling module 3 of the insulated container I by means of the device 13. The cooling module I comprises a coolant inlet 4 which is fed by the injection tube 4 to the device 13. The injection tube 14 is connectable to the supply an orifice 4 for liquefied nitrogen and an orifice 5 of the insulated container 1. A solenoid coil 15 is mounted around the injection tube 4. The coil 15 is hollow inside. A supply line 16 is arranged in the hollow space. A detector (not shown) can be assigned to the coil 5 to detect its function. The device 13 may additionally comprise an adjusting device. By means of this, for example, the ambient air temperature around the container 1 or the temperature required in the container can be adjusted by means of the temperature setting and indicating means and / or the desired cooling time for the insulated container 1 can be preselected by means of the corresponding setting and indicating means. . Based on these temperature and time (time) values, the corresponding amount of coolant is set and controlled.

The coolant supply can, for example, be controlled by a pluggable and disconnectable cotton pump and a solenoid valve or slider on the medium supply. Other control options can also be envisaged and the invention does not exclude these possibilities. The coolant is supplied by operating the control device. In conjunction with the corresponding dimensioning of the injection tube T4, a particularly desired amount of coolant can be supplied to the cooling module 3.

According to the invention, it is ensured that injection can occur only when the connection between the injection tube 14 and the cooling module 3 is reliably established. For this purpose, it is proposed that the actuating device can only open the closing device if it is a corresponding sensor, e.g. detects the presence of a closed magnetic field, indicating the proper functioning of the electromagnet. These arrangements both increase safety for the operator and eliminate the negative effects on the environment.

Claims (18)

1. An insulated container with a cooling module and a device (13) for supplying coolant, the insulated container (1) comprising a thermal vacuum insulation and made of stainless steel having a filling opening (5) in the region of its upper wall (2). which is in connection with the inlet opening (4) of the cooling module (3) for supplying the cooling medium to the cooling module (3), the cooling module (3) having at least one outlet opening (7) for escaping the cooling medium into the interior a container (1) for cooling it, the filling opening (5) of the insulated container (1) being connectable to the coolant supply device (13), characterized in that the coolant supply device (13) comprises, in the region of its end, a fill orifice (5) magnetic or electromagnetic means that interact with corresponding magnetizable or magnetic by means in the area of the filling opening (5) of the insulated container (1) for connecting a device (13) for supplying cooling medium to the insulated container (1) or the cooling module (3), respectively. 2. Isolated container. according to claim 1, characterized in that the device (13) for supplying the contents cooling medium in the region of its end connectable to the insulated filling opening (5) 20, the annular steel disc (8) being mounted in the region of the filling opening (5). An insulated container according to claim 1 or 2, characterized in that the vacuum in the thermal vacuum insulation of the cooling module (3) is 0.001 to 0.1 kPa (0.01 to 1 mbar). An insulated container according to any one of claims 1 to 3, characterized in that the cooling module (3) comprises a very low temperature cooling medium, substantially liquefied nitrogen. An insulated container according to any one of claims 1 to 4, characterized in that the filling The opening (5) is closable by means of closing means which do not protrude beyond the surface of the top wall (2) of the insulated container (1). Insulated container according to claim 5, characterized in that at least a part of the closing means of the filling opening (5) cooperates with the means of the device (13) for supplying the cooling means. 35 for connecting the device (13) for supplying the cooling medium to the insulated container (1) or the cooling module (3), respectively. An insulated container according to claim 6, characterized in that the coolant supply device (13) is associated with a feed quantity control device comprising a closed device 40 and a timer connected to the shutter device to control the duration of the coolant supply. to a cooling module (3) to supply a different amount of cooling medium to the cooling module (3). An insulated container according to any one of claims 1 to 7, characterized in that it is a cooling container The module (3) is detachably coupled to the insulated container (1), and includes devices that are in operative communication with corresponding insulated container devices (1) to allow insertion and storage of the cooling module (3) in the insulated container (1). An insulated container according to any one of claims 1 to 8, characterized in that in the insulated container (1) at least one cooling module (3) and at least one cold storage storage plate are arranged side by side. -6GB 303202 B6 An insulated container according to any one of claims 1 to 9, characterized by. The outlet opening (7) of the cooling module (3) is simultaneously an inlet opening (4). An insulated container according to any one of claims 1 to 10, characterized in that the storage container 5 the volume of the coolant module (3) for the coolant corresponds to the weight of coolant to be used, 500 to 15 000 g. Method for filling a cooling module (3) in an insulated container (1) with a cooling medium, wherein the cooling medium is fed to the cooling module (3) from above through a filling opening (5) in the upper and wall of the insulated container (1) and inlet (4) a cooling module (3) communicating with said opening (5), wherein the cooling medium is allowed to escape from the cooling module (3) via at least one outlet opening (7) into the interior of the insulated container (1) for cooling it, During the filling process, a coolant supply device (13), indicated by a coil (13), is connected to the insulated container (1) or the cooling module (3). 15, said connection being ensured by a magnetic force. Method according to claim 12, characterized in that the magnetic force is applied by means of an electromagnet in the region of the end of the coolant supply device (13) connectable to the filling opening (5) and by means of a steel disc (8) mounted in the filling opening region. (5). Method according to claim 12 or 13, characterized in that 800 to 1200 g of cooling medium are evaporated per hour. A method according to any one of claims 12 to 14, characterized in that the duration is 25 controlling the supply of coolant to the cooling module (3) by means of a control device associated with the charging device for supplying varying amounts of coolant to the cooling module (3), so that refrigeration is set for the desired time within the insulated container (1) . 30 Process according to any one of claims 12 to 15, characterized in that liquefied nitrogen is used as the very low-temperature cooling medium. Use of an insulated container according to any one of claims 1 to 11, or a method according to any one of claims 12 to 16, for storing temperature-sensitive substances in a cold state for a limited period of time. Use according to claim 17 for cooling foodstuffs.