PL195850B1 - Insulated container with fillable cooling module - Google Patents

Abstract

1. An arrangement comprising an insulating container and a device for supplying coolant to the insulating container, the container having in the region of the upper wall a filling opening which is connected to a supply opening of a cooling module, the cooling module having at least one opening discharge, through which the coolant is discharged into the internal chamber of the insulating container, and the filling opening of the insulating container is connected to a device for supplying coolant, characterized in that the device (13) for supplying coolant in the area of its end, connected to the filling opening (5) has magnetic or electromagnetic elements that cooperate with appropriate magnetized or magnetic elements in the area of the filling opening (5) of the insulating container (1), for connecting a device for supplying coolant to the insulating container (1) or cooling module (3). PL PL PL

Description

The present invention relates to a system comprising an insulating container and a coolant supply device, and a method for filling a cooling module in an insulating container, which is preferably used for the periodic preservation of temperature-sensitive goods, preferably for cooling foodstuffs.

Methods that prevent spoilage of foodstuffs or other temperature-sensitive materials have been known for a long time. In particular, cooling can be used to preserve most processed foods, since the physical, chemical, microbiological and enzymatic reactions slow down as the temperature lowers.

Therefore, for the transport and storage of perishable goods, especially foodstuffs, containers with thermally insulated walls (insulating containers) were used. As a rule, the insulating containers are additionally cooled in order to keep the temperature inside the insulating container low for a longer period.

Solid or liquid carbon dioxide or liquid nitrogen is used to cool the insulating containers. For example, in the process Gryogen ^® trans, liquid nitrogen, stored in a vacuum-insulated container at refrigerated car is sprayed in gaseous form in the hold where the hold of the air it draws heat energy for cooling included in the material of temperature-sensitive (Gas actuell, issue 51, p. 8, Messer Griesheim GmbH, 1986). For cooling purposes, cold storage plates are also used, which are filled with a so-called "eutectic liquid" or cooling brine.

In the case of cooling modules that are filled with deeply cooled, liquid or snow-shaped carbon dioxide or deep-cooled liquid nitrogen as coolant, the filling connection is usually located on the front side of the cooling module, so that filling is only possible after opening the container door insulating. This is disadvantageous in that with each filling process, cold escapes from the insulating container into the mostly warmer surrounding space. Therefore, any filling process involves a loss of cold which can reduce the quality of the temperature sensitive substances in the insulating container.

The present invention relates to a system comprising an insulating container and a device for supplying coolant to the insulating container, the container having a filling opening in the area of the top wall which is connected to the supply opening of the cooling module. The cooling module has at least one discharge opening through which the coolant is discharged into the inner chamber of the insulating vessel and the filling opening of the insulating vessel is connected to the coolant supply device.

The essence of the invention is that the coolant supply device in the area of its end connected to the filling opening has magnetic or electromagnetic elements that cooperate with corresponding magnetized or magnetic elements in the area of the filling opening of the insulating container for connecting the coolant supply device to the insulating container. or cooling module.

Preferably, the filling opening is closed by closing means that do not protrude above the top wall surface of the insulating container.

The cooling module is made of stainless steel and has thermal vacuum insulation.

In the solution according to the invention, connected to the coolant supply device is an amount control device that includes a cut-off device and a timer operably connected to the cut-off device by which the period of coolant supply to the cooling module is controlled for supply to the cooling module. varying amounts of coolant.

The cooling module is releasably connected to the insulating container and comprises devices which are operably connected to the corresponding devices of the insulating container and allow the cooling module to be inserted and inserted into the insulating vessel, wherein in the insulating vessel at least one cooling module is arranged adjacent to at least one storage plate. cold, and the cooling module exhaust opening is also the supply opening.

PL 195 850 B1

The capacity of the cooling module for the coolant is 500 g - 15,000 g.

The invention also relates to a method of filling a cooling module in an insulating container with coolant by means of a coolant supply device, in which the coolant is supplied to the cooling module from above through a filling opening in the upper wall of the insulating container and through a cooling module supply opening connected thereto, the coolant being from the cooling module it is fed through at least one discharge opening to the inner chamber of the container. The essence of the invention is that during the filling process, the coolant supply device engages the insulating container or the cooling module by means of a magnetic force, the magnetic force being transmitted by means of electromagnets in an area connected to the filling opening of the coolant supply device end, and with a steel disc placed in the area of the filling opening. According to the invention, by means of a control device associated with the filling device, the length of the period of coolant supply to the cooling module is controlled in order to supply the cooling module with different amounts of coolant and set the periodically required cold preservation of the materials inside the insulating container.

An advantage of the invention is that, without opening the door of the insulating container, it is possible to reliably and technically easily carry out the process of filling the cooling module with coolant.

The term "insulating container" is understood to mean all possible types of at least partially closed containers, for example containers, wardrobes, transport trolleys or wagons, which have thermally insulated walls and in which temperature-sensitive products can be stored or transported at a certain temperature by specified time.

The term "coolant" is understood to mean in particular a deeply cooled, liquefied gas or gaseous mixture which, at normal room temperature (about 23 ° C) and under normal pressure (about 100 Pa), is present as a gas, for example nitrogen, carbon dioxide or air and which at the appropriate temperature and pressure is in a liquid, supercritical or solid state, the term "solid" also encompassing the form of nuggets, granular or snowflakes.

Preferably, the cooling module comprises deeply chilled, substantially liquid nitrogen as the coolant, the deeply cooled nitrogen is collected in the cooling module substantially in liquid form, evaporates over time and escapes as a gaseous substance into the inner chamber of the container through the drain hole in the cooling module. to keep it cool.

For example, the coolant supply device at its end connected to the filling opening has magnetic or electromagnetic means which cooperate with suitable magnetized or magnetic means in the region of the filling opening of the insulating container to connect the coolant supply device to the insulating container or cooling module. The steel target is made of a material which is a magnetic or a magnetized material, for example chrome or nickel steel. The injection tube is made, for example, of a metallic material, for example copper or stainless steel, and the outlet opening for the coolant in the injection tube is selected in accordance with the desired volume flow. The term "injection tube" is understood to mean all possible types of injection devices, for example nozzles and lances, which are suitable for introducing a coolant or a cooling module. In addition, the device for supplying coolant to the cooling module has a supply line which is connected to a pressurized coolant source.

According to the invention, it is provided that the cooling module is made of stainless steel and has thermal vacuum insulation. The vacuum in the thermal vacuum insulation of the cooling module is 0.001 - 0.1 Pa. In order to improve the hermetic insulating properties, at said vacuum pressure, it is possible to fill the inner chamber with carbon dioxide or argon. According to the invention, the height of the cooling module is 50-200 mm, preferably 60-100 mm.

The use of at least one cold supply plate has the advantage that part of the cooling capacity of the coolant can be absorbed first by the cold supply plate. In this way, an initial insufficient cooling of the goods to be cooled can advantageously be avoided. The cold is then released from the reservoir plate, which significantly extends the cooling time. Thus, the cold storage plate acts as a cold buffer and a cold storage. According to the invention, the cold storage plate is placed below the cooling module in an insulating container. In this

The cold storage plate preferably acts as a buffer against the excessively 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 supply plate.

The eutectic fluid has a freezing point of from 0 to -40 ° C, more preferably from about -2 to -4 ° C.

The amount of coolant to be filled depends on the number of parameters, for example, it is dependent on the ambient temperature, the temperature to be maintained in the insulating vessel, the starting temperature of the insulating vessel, the type of product contained in the insulating vessel, the duration of the cooling, the method of transport and / or the type and the size of the insulating container. For example, ship tanks require very large amounts, and only insignificant amounts (up to a few grams) of coolant are needed for isolation containers for vaccines or for certain trolleys.

The inner surface of the substantially vertical walls of the insulating container is formed, for example by a defined lamellar surface structure, such that the gaseous coolant which is formed in the upper region of the insulating container falls better or flows into the lower region of the insulating container. Thereby, the temperature distribution inside the insulating container can be improved.

Preferably, 800-1200 g of the coolant is evaporated in one hour, cooling the inner chamber of the insulating vessel.

The length of the coolant supply period to the cooling module is controlled by a control device associated with the filling device to provide the cooling module with varying amounts of coolant and thus set periodically the desired cold preservation of the materials inside the insulating vessel. By controlling the filling time for a given coolant pressure in the filling process, varying amounts of coolant can be supplied to the cooling module to control the timing of desired cold preservation of goods in the insulating container. Advantageously, for certain application cases, it is possible to alternatively or additionally use coolant pressure control to control the amount of coolant supplied.

Deep cooled, liquefied nitrogen is used as a coolant.

The products can be pre-cooled and / or frozen with the device and method according to the invention. In this way, it is possible to advantageously use the solution according to the invention in the storage of fresh produce, to protect against oxidation and to extend the shelf life of the fresh goods.

The subject matter of the invention is shown in the embodiment in the drawing, in which fig. 1 shows a perspective view of an insulating container with a cooling module, fig. 2 - a section through the upper region of an insulating container and a cooling module with a closure of an insulating container, fig. 3 - a section through an upper region of the insulating vessel and cooling module, and a portion of a device for supplying coolant to the cooling module connected to the insulating vessel.

The insulating container 1 shown in FIG. 1 has thermally insulated walls 2. Inside the insulating container 1 a cooling module 3 is placed. The cooling module 3 has a feed opening 4 which is connected to a filling opening 5 of the insulating container. The top surface (hatched surface) of the wall 2 of the insulating container is provided with a trough-shaped recess 6, and the cooling module 3 has an outlet 7 for the coolant.

2, the closure of the insulating container 1 is shown in more detail. In the area of the filling opening 5 of the insulating container 1, there is a trough 6 with an annular steel plate 8 arranged therein, the steel plate 8 being thus built into the insulating material of the thermally insulated wall 2 of the insulating container 1, that no elements protrude above the surface of the top wall 2 of the insulating container. As a closure of the filling opening 5, for example, a permanent ring magnet 9 can be used, in the center of which the insulating material 10 is arranged so that it fits into the wall passage 11 of the filling opening 5 and seals it. Thus, it is possible to largely eliminate cold losses. The wall opening 11 can be formed as a pipe section and can be closed with the outer wall 12 of the cooling module 3. The steel disc is made of a magnetic or magnetized material, for example chrome or nickel steel.

Fig. 3 shows a system for supplying coolant to the cooling module 3 of the insulating container by means of a device 13. The cooling module 3 has a supply opening 4.

The injection tube 14 can be connected to a liquid nitrogen supply opening 4 or a filling opening 5. Around the injection tube 14 is a solenoid coil 15. Coil 15 is hollow inside. A lead-in conductor 16 is arranged in the void. A detector (not shown here) for detecting the operation of the coil can be assigned to the coil 15. In addition, the device 13 can include associated setting devices. With these devices, it is possible, for example, to set the ambient air temperature of the insulating container 1 or the required temperature in the insulating container 1 by means of a temperature setting and display device, and / or the desired cooling time for a given insulating container 1 can be preselected by means of a setting and time display device. Based on these temperature and time values, the appropriate amount of coolant supplied is set and controlled.

The supply of coolant can, for example, be regulated by means of a detachably connected feed pump and by means of a magnetic valve or a slide valve for the coolant. Other control methods are also possible and not excluded. The coolant supply is preferably accomplished by actuating an actuator. In connection with the suitability of the injection tube 14, a particularly desired amount of coolant can be supplied to the cooling module 3.

According to the invention, it is provided that the injection can only take place when a reliable connection has been established between the injection tube 14 and the cooling module 3. It is therefore provided that, for example, the actuator can only open the shut-off device when a corresponding sensor, which detects the presence of a closed magnetic field, for example , indicates the correct operation of the solenoid. By these technical measures, on the one hand, the safety of the operating personnel is increased and, on the other hand, a better environmental compatibility is ensured.

Claims (11)

An arrangement comprising an insulating container and a device for supplying coolant to the insulating container, the container having a filling opening in the area of the top wall which is connected to a supply opening of a cooling module, the cooling module having at least one discharge opening through which the coolant is discharged. is to the inner chamber of the insulating vessel, and the filling opening of the insulating vessel is connected to a coolant supply device, characterized in that the coolant supply device (13) in the region of its end connected to the filling opening (5) has magnetic or electromagnetic means which cooperating with suitable magnetized or magnetic elements in the area of the filling opening (5) of the insulating container (1) for connecting the coolant supply device to the insulating container (1) or cooling module (3). 2. The system according to claim A method as claimed in claim 1, characterized in that the filling opening (5) is closed by closing means that do not protrude above the surface of the top wall (2) of the insulating container (1). 3. The system according to p. A device as claimed in claim 1, characterized in that the cooling module (3) is made of stainless steel and has a vacuum thermal insulation. 4. The system according to p. A device as claimed in claim 1 or 3, characterized in that an amount control device is connected to the coolant supply device (13), which comprises a cut-off device and a timer operably connected to the cut-off device by means of which the period of coolant supply to the cooling module is controlled, to supply varying amounts of coolant to the cooling module. 5. The system according to p. A device as claimed in claim 1, characterized in that the cooling module (3) is releasably connected to the insulating container (1) and comprises devices which are functionally connected to the corresponding devices of the insulating container (1) and allow the cooling module to be inserted and inserted into the insulating container. 6. The system according to p. A method as claimed in claim 1 or 5, characterized in that in the insulating container (1) at least one cooling module (3) is arranged next to at least one cold storage plate. 7. The system according to p. The cooling module as claimed in claim 1, characterized in that the discharge opening (7) of the cooling module is also the supply opening. PL 195 850 B1 8. The system according to p. The method of claim 1, wherein the capacity of the cooling module for the coolant is 500 g - 15,000 g. 9. Method of filling a cooling module in an insulating container with coolant by means of a coolant supply device, in which the coolant is supplied to the cooling module from above through a filling opening in the top wall of the insulating container and through a cooling module supply opening connected thereto, the coolant from the module is supplied through at least one discharge opening to the inner chamber of the container, characterized in that during the filling process, the coolant supply device (13) engages the insulating container (1) or the cooling module (3) by means of a magnetic force. 10. The method according to p. A device as claimed in claim 9, characterized in that the magnetic force is transmitted by means of electromagnets in the area of the end of the coolant supply device (13) connected to the filling opening (5) and by means of a steel disc (8) placed in the area of the filling opening (5). 11. The method according to p. A method according to claim 9 or 10, characterized in that by means of a control device associated with the filling device the length of the period of supply of the coolant to the cooling module (3) is controlled in order to supply the cooling module (3) with different amounts of coolant and to adjust the periodically required cold preservation of the materials inside. the insulating container (1).