奥地利专利AT517516A1 Transport container for transporting temperature-sensitive cargo

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优先权

专利摘要:
In a transport container for the transport of temperature-sensitive cargo comprising an interior for receiving the cargo and an enclosure enclosing the interior, comprising a thermal insulation, wherein at least one latent heat storage and at least one active tempering are provided to temper the interior, the shell is formed multi-layered , wherein the thermal insulation, the latent heat storage and optionally the active tempering are formed as separate from each other, superimposed layers of the shell.
公开号:AT517516A1
申请号:T518/2015
申请日:2015-08-04
公开日:2017-02-15
发明作者:
申请人:Rep Ip Ag；
IPC主号:

专利说明:

The invention relates to a transport container for the transport of temperature-sensitive cargo comprising an interior for receiving the cargo and an enclosure enclosing the interior, comprising a thermal insulation, wherein at least one latent heat storage and at least one active tempering are provided to temper the interior.
When transporting temperature-sensitive goods to be transported, such as For periods of several hours or days, prescribed storage and transport temperature ranges must be maintained to ensure the usability and safety of the medicinal product. Temperature ranges from 2 to 25 ° C, especially 2 to 8 ° C as storage and transport conditions are prescribed for various drugs.
The desired temperature range can be above or below the ambient temperature, so that either cooling or heating of the interior of the transport container is required. If the ambient conditions change during a transport operation, the required temperature control may include both cooling and heating. So that the desired temperature range during transport is permanently and demonstrably adhered to, transport containers with special insulation capacity are used. These containers are equipped with passive or active tempering elements. Passive tempering require during use no external power supply, but use their heat storage capacity, and depending on the temperature level to a release or absorption of heat to or from the temperature to be tempered transport container interior. However, such passive tempering are exhausted as soon as the temperature compensation is completed with the transport container interior.
A special form of passive tempering are latent heat storage, which can store thermal energy in phase change materials whose latent heat of fusion, heat of solution or heat of absorption is much greater than the heat they can store due to their normal specific heat capacity. A disadvantage of latent heat storage is the fact that they lose their effect as soon as the entire material has completely gone through the phase change. However, by performing the reverse phase change, the latent heat storage may be recharged.
Active temperature control elements require an external energy supply for their operation. They are based on the transformation of a non-thermal energy form into a thermal energy form. The release or absorption of heat is carried out, for example, in the context of a thermodynamic cycle, such. by means of a
Compression chiller. Another embodiment of active temperature control elements operates on the basis of the thermoelectric principle, whereby so-called Peltier elements are used.
Transport containers have already become known in which active and passive temperature control elements are combined with one another such that the active temperature control elements are used to recharge the latent heat storage devices as needed. In the US 2015/166262 Al will be a
Transport container described that has been effective in a separate from the receiving space for the cargo container area as cooling elements and effective as heating elements latent heat storage. By means of a blower, an air circulation is generated, in which air is passed either over the surface of the effective cooling elements as a cooling elements or over the surface of the heating elements acting as latent heat storage and the tempered such air is transported into the receiving space for the cargo. In the
Latent heat storage elements run lines that can be traversed by actively cooled or heated medium to recharge the latent heat storage. The lines are part of a compression refrigeration machine whose components can be arranged in a separate area of the transport container.
In the subject matter of US 2004/226309 Al, air that has been cooled in the heat exchange with a compression refrigeration machine, passed into the receiving space for the cargo to cool the cargo there. The cooled air can also be blown over the surfaces of a latent heat storage to charge this, so that a temperature of the transported material is guaranteed even after switching off the active Temperierungssystems.
WO 2004/080845 Al also describes a transport container with active and passive
Tempering. The main cooling takes place by means of a compression refrigeration machine. As a backup system, a latent heat storage is provided, which can be charged by heat exchange with the compression refrigeration machine. In passive backup operation, air is used over surfaces of the
Latent heat storage blown to temper the transported goods with the so-tempered air.
A disadvantage of the systems described is that the active and / or passive tempering are arranged in a separate, mostly separated area of the container, so that an air circulation must be generated, with which the heat transfer between the receiving space for the cargo and the tempering takes place. In order to generate the required air circulation blowers are necessary, which consume electrical energy, so that appropriate storage capacities must be made available and transported.
Furthermore, it should be noted that the energy input into the transport container is heterogeneous during transport. If the container is exposed to heat radiation, the energy input in the area of the radiation effect is significantly greater than in the areas in which no radiation acts on the container. Nevertheless, the temperature inside the container must be kept constant and homogeneous within a permissible range. With inhomogeneous energy input there is the problem that the latent heat storage is not consumed homogeneously. Thus, it comes in the interior of the transport container after a certain time to local temperature changes. If the local temperature changes exceed or fall below a certain threshold, the cargo is no longer protected.
The invention therefore aims to overcome the abovementioned disadvantages and to improve a transport container in such a way that the power consumption is reduced, a compact and simple construction is created and the susceptibility to errors is reduced. Furthermore, local temperature differences in the interior of the transport container should be avoided as far as possible.
To solve this problem, the invention essentially provides, in a transport container of the type initially mentioned, that the casing has a multilayer structure, wherein the thermal insulation, the latent heat storage and optionally the active tempering element are formed as separate layers of the casing lying one above the other. The layer structure according to the invention makes it possible to integrate the latent heat accumulator and the active temperature directly into the wall elements delimiting the interior space, wherein the individual layers are in contact with the interior through heat conduction, in order to temper it together with the transport material located therein. Heat transfer by convection, i. by actively circulating air, is therefore not required, so that it can be dispensed with the necessary blower and the like. This can reduce power consumption and the susceptibility to errors. Furthermore, the provision of a separate area of the container for the arrangement of refrigeration units and the like can be dispensed with.
The integration of the latent heat accumulator and the active tempering in layers of walls bounding the interior further facilitates the construction of the container. The multi-layer walls can be provided as prefabricated modules, so that a modular assembly of transport containers is made possible.
Another advantage of the embodiment of the invention is the uniform heat input into the interior and in the large surface, which is available for heat transfer. In this context, a preferred embodiment provides that the latent heat storage layer, the insulating layer and optionally the active tempering layer completely surround the interior space.
The layer provided with the active tempering element, i. the tempering, can be used to charge the latent heat storage layer when needed.
Alternatively or additionally, the
Latent heat storage layer but also used to temper the interior of the container directly. The active tempering element can also be integrated into the latent heat storage layer. The tempering element may comprise, for example, cooling or heating coils which run in the latent heat storage layer.
In the context of the invention, it is not mandatory that the three layers, i. the insulating layer, the latent heat storage layer and optionally the active tempering layer are arranged directly on top of each other, i. lie directly on each other. Two layers in each case can also be connected to one another with the interposition of a further layer. The further layer may be an adhesive layer which serves to bond the two layers together, or a functional layer.
Furthermore, the invention is not limited to the fact that the layer structure of the shell comprises only a single latent heat storage layer, insulating layer and active tempering. Rather, embodiments are also conceivable in which two or more latent heat storage layers, two or more insulating layers and / or two or more active tempering layers are provided.
A preferred embodiment provides that at least two of the three layers (latent heat storage layer, insulating layer, tempering layer), in particular all three superimposed layers, are in heat-conducting connection with each other, in particular in full-surface contact with each other.
In a particularly simple manner, the transport container is cuboidal and the shell consists of six walls, each of which wall is formed at least three layers and a latent heat storage layer, an insulating layer and an active tempering comprises. One of the six walls can be designed as a door.
The transport container according to the invention can be used as a standardized ISO container (20 or 40 feet) or as
Air freight container, in particular as a standardized "unit load device" be formed, wherein the container walls, that is, the outer walls of the container have the layer structure according to the invention.
The active tempering layer is preferably one for converting electrical energy into heat to be emitted or absorbed. For the purpose of supplying the required electrical energy of the transport container is preferably equipped on its outer side with connecting means, in particular a socket, for electrically connecting an external power source. As soon as an external power source is available, the active temperature control layer can thus be put into operation.
Furthermore, it can be provided that the transport container has an electrical energy store, such as an electric energy storage device. an accumulator, which can be fed by an external power source. The electrical energy storage can be arranged to control and possibly
Supply temperature monitoring electronics of the transport container with electrical energy. Furthermore, the electrical energy store can be connected to the active tempering layer in order to supply it with electrical energy when needed. As a result, an at least short-term operation of the active temperature control layer is also possible during transport if no external power source is present.
A preferred embodiment provides that the active tempering layer has Peltier elements, a heat exchanger cooperating with a thermodynamic cycle, in particular a compression refrigeration machine, or a magnetic cooling system. Peltier elements are particularly preferably used because they can be made physically small and can be integrated in a simple manner into the tempering layer. The tempering layer preferably comprises a plurality of Peltier elements whose cold and warm sides are each connected to a common plate-shaped heat-conducting element. The plate-shaped heat-conducting elements thus form the top and the bottom of the tempering and carry interposed Peltier elements.
Within the scope of the invention, various arrangements of the individual layers are possible. According to a first variant, it is provided that the insulating layer is arranged between the further outward tempering layer and the more inward latent heat storage layer. This design with an externally arranged tempering layer has particular advantages if the active tempering layer comprises Peltier elements, since these require a strong external energy output.
Alternatively, however, it can also be provided that the insulating layer is arranged further outward than the tempering layer and the latent heat storage layer. Thus, the tempering and the
Latent heat storage layer effectively protected against external heat.
A further variant provides in this context that the tempering layer is arranged between the outer insulating layer and the latent heat storage layer. This arrangement of the layers has the effect that the innervated latent heat storage layer additionally homogenizes the temperature in the interior. This is especially true in the design of the active tempering layer with mechanically applied energy, e.g. by means of a compression refrigeration machine, an advantage.
Another variant provides that the
Latent heat storage layer between the outer insulating layer and the tempering layer is arranged. This training is in an embodiment of the active temperature control layer with mechanically supplied energy, e.g. by means of a compression refrigeration machine, or with a magnetic cooling particularly suitable if the interior of the transport container must be actively cooled thereby quickly because no delay caused by the latent heat storage layer.
As an additional measure to avoid the negative effects of heterogeneous externally applied energy, it can preferably be provided that further an energy distribution layer of a highly thermally conductive material for uniform distribution of externally applied to the container thermal energy within the energy distribution layer is arranged the energy distribution layer is preferably arranged further outside than the latent heat storage layer. The energy distribution layer preferably has a thermal conductivity of
, prefers
In order to achieve a homogenization of the temperature prevailing in the interior of the transport container, alternatively or additionally, an energy distribution layer may be arranged on the side of the latent heat storage layer facing the interior. The energy distribution layer preferably has a thermal conductivity of
, prefers
In order to promote a uniform distribution of energy in the interior, the innermost layer is the
Container wall preferably formed with a high emissivity and / or high thermal conductivity. With regard to the thermal conductivity, the innermost layer may be formed as an energy distribution layer as mentioned above (thermal conductivity of λ> 100 W / (m.K), preferably λ> 200 W / (m.K)). The innermost layer is the layer directly in contact with the interior or delimiting it. In this case, in order to sufficiently ensure the removal of energy from the interior space or the energy supply to the interior, so that e.g. If the goods to be warmed up can be cooled down without convection or the entire interior space can be used for the cargo, the condition of the innermost vision is decisive. This can be treated so that the thermal radiation is increased, with the achievement of an emissivity of> 0.1, preferably between 0.5 and 1 is preferred. The increase in emissivity can be achieved by surface treatment, e.g. for metals by grinding or painting, for aluminum by chromating. Alternatively, or in addition, the heat transfer between the innermost vision and the cargo may be increased by increasing the surface area through structures such as e.g.
Waves with a radius of min. 5mm, ideally the surface should be increased by at least 30%.
The latent heat storage layer is preferably formed as a planar chemical latent heat storage, with respect to the latent heat storage medium forming conventional training can be used. Preferred media for the latent heat storage are paraffins and salt mixtures. Of the
Phase transition of the medium is preferably in the temperature range of 0-10 ° C or between 2-25 C.
The insulating layer is preferably formed as a vacuum insulation. The insulating layer preferably comprises at least one cavity which is evacuated. Alternatively, the at least one cavity may be filled with a gas that is poorly heat-conductive. Furthermore, the insulating layer may have a honeycomb-like structure. An advantageous embodiment results when the insulating layer has a plurality of particular honeycomb-shaped hollow chambers, wherein a honeycomb structural element according to WO 2011/032299 Al is particularly advantageous.
The invention will be explained in more detail with reference to an embodiment schematically illustrated in the drawing.
In Fig. 1, a cuboid transport container 1 is shown, whose walls are designated 2, 3, 4, 5 and 6. On the sixth side of the transport container 1 is shown open so that the layer structure of the walls is visible. The open side can for example be closed by means of a door having the same layer structure as the walls 2, 3, 4, 5 and 6. The six walls of the transport container 1 all had the same layer structure. The layer structure comprises an outer layer 7, a middle layer 8 and an inner layer 9.
According to a first variant, the layer 7 is an active tempering element, such as e.g. a layer provided with Peltier elements, the layer 8 an insulating layer and the layer 9 a latent heat storage layer.
According to a second variant, the layer 7 is an insulating layer, the layer 8 is an active tempering element and the layer 9 is a latent heat storage layer.
According to a third variant, the layer 7 is an insulating layer, the layer 8 is a latent heat storage layer and the layer 9 is an active tempering.

权利要求:
Claims (13)
[1]
Claims:
1. Transport container for the transport of temperature-sensitive cargo comprising an interior for receiving the cargo and an enclosing the interior shell, which comprises a thermal insulation, wherein at least one latent heat storage and at least one active tempering are provided to temper the interior, characterized in that the Shell is formed multi-layered, wherein the thermal insulation, the latent heat storage and possibly the active temperature control are formed as separate from each other, superposed layers of the shell.
[2]
2. Transport container according to claim 1, characterized in that at least two, in particular all three, superimposed layers in heat-conducting connection to each other, in particular in full-surface contact with each other.
[3]
3. Transport container according to claim 1 or 2, characterized in that the latent heat storage layer, the insulating layer and possibly the active tempering completely surround the interior of each.
[4]
4. Transport container according to claim 1, 2 or 3, characterized in that the transport container is cuboid and the shell consists of six walls, each of which wall is formed at least three layers and a latent heat storage layer, an insulating layer and an active tempering comprises.
[5]
5. Transport container according to claim 4, characterized in that one of the six walls is designed as a door.
[6]
6. Transport container according to one of claims 1 to 5, characterized in that the active temperature-control layer is designed for converting electrical energy into heat to be emitted or absorbed.
[7]
7. Transport container according to one of claims 1 to 6, characterized in that the active tempering layer Peltier elements, a cooperating with a thermodynamic cycle, in particular a compression refrigeration heat exchanger or a magnetic cooling.
[8]
8. Transport container according to one of claims 1 to 7, characterized in that the insulating layer is disposed between the further outward tempering layer and the more inner latent heat storage layer.
[9]
9. Transport container according to one of claims 1 to 7, characterized in that the insulating layer is arranged further outside than the tempering layer and the latent heat storage layer.
[10]
10. Transport container according to claim 9, characterized in that the tempering layer is arranged between the outer insulating layer and the latent heat storage layer.
[11]
11. Transport container according to claim 9, characterized in that the latent heat storage layer between the outer insulating layer and the tempering layer is arranged.
[12]
12. Transport container according to one of claims 1 to 11, characterized in that further a Energieverteilschicht is arranged from a highly thermally conductive material for uniform distribution from the outside acting on the container thermal energy within the energy distribution layer, wherein the energy distribution layer preferably further out than the latent heat storage layer is.
[13]
13. Transport container according to claim 12, characterized in that a further energy distribution layer is provided, wherein each one energy distribution layer is arranged on both sides of the latent heat storage layer.

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE1126426B|1960-03-08|1962-03-29|Philips Nv|Small cooling device with a Peltier cooling arrangement|

DE2517921A1|1975-04-23|1976-11-04|Philips Patentverwaltung|LATENTHEAT STORAGE|

GB1569134A|1976-10-11|1980-06-11|Astra Sjuco Ab|Res in a heat-insulated container method and apparatus for storing goods at stable temperatu|

DE3044202C2|1980-11-24|1982-10-07|Alfred Schneider KG, 7630 Lahr|Method and device for introducing crystallization nuclei into a liquid latent heat storage medium|

ES2103841T3|1991-03-19|1997-10-01|Behr Gmbh & Co|ARRANGEMENT AND PROCEDURE FOR REFRIGERATING OR HEATING A CABIN.|

DE4142843A1|1991-09-26|1993-04-01|Wolfgang Wasserthal|Portable cool container pref. powered from solar energy or car battery - comprises insulated cover and underpart and at least one thermo-electric heat pump|

US6105659A|1996-09-12|2000-08-22|Jaro Technologies, Inc.|Rechargeable thermal battery for latent energy storage and transfer|

JP3054754U|1997-11-08|1998-12-18|欣融汽車有限公司|Car cooler box|

WO2000021830A1|1998-10-12|2000-04-20|Tineke Charlotte Kouwenberg|Cooled drawer for aircraft food trolley|

GB9915265D0|1999-07-01|1999-09-01|Kryotrans Ltd|Thermally insulated container|

JP4213465B2|2000-11-02|2009-01-21|テルレックス・コーポレイション|Temperature controlled storage system|

US20020162339A1|2001-05-04|2002-11-07|Harrison Howard R.|High performance thermoelectric systems|

US7422143B2|2002-10-23|2008-09-09|Minnesota Thermal Science, Llc|Container having passive controlled temperature interior|

JP2004156839A|2002-11-07|2004-06-03|Sanyo Electric Co Ltd|Canned beverage cooler and canned beverage cooling method|

US20040226309A1|2003-02-17|2004-11-18|Broussard Kenneth W.|Temperature controlled, pallet-sized shipping container|

SE0300683L|2003-03-13|2004-09-14|Aircontainer Ac Ab|Air freight container with temperature control unit and such temperature control unit|

JP2004317041A|2003-04-17|2004-11-11|Yaskawa Electric Corp|Temperature control device|

US20060248902A1|2005-05-06|2006-11-09|Adam Hunnell|Temperature regulation device for a fluid-containing receptacle and use thereof|

DE202006010757U1|2006-07-11|2006-11-02|Sgl Carbon Ag|A method for providing an open refrigerated display cabinet with uniform temperature maintenance has an inner liner within the thermal insulation comprising a phase change material and graphite|

ITMI20071259A1|2007-06-22|2008-12-23|High Technology Partecipation|REFRIGERATOR FOR FRESH PRODUCTS WITH PASSIVE MEANS OF UNIFORMING TEMPERATURE WITHOUT VENTILATION AND MAINTAINING THERMAL PERFORMANCES AND RELATIVE HUMIDITY EVEN IN THE ABSENCE OF ELECTRICITY.|

US20090078708A1|2007-09-20|2009-03-26|Preston Noel Williams|Temperature Maintaining Package Having Corner Discontinuities|

DE102008032150A1|2008-07-08|2010-01-14|Braun Gmbh|Electric shaver with integrated cooling|

EP2177849A1|2008-10-20|2010-04-21|Nederlandse Organisatie voor toegepast-natuurwetenschappelijk Onderzoek TNO|Container for storing articles at a predetermined temperature|

GB2459392B|2009-05-29|2010-04-07|Softbox Systems Ltd|Transport container|

US20110067852A1|2009-09-21|2011-03-24|David Scott Farrar|Temperature controlled cargo containers|

WO2011044042A1|2009-10-05|2011-04-14|Robert Bosch Gmbh|Energy storage system including an expandable accumulator and reservoir assembly|

CN102200366A|2010-03-25|2011-09-28|青岛德莱维电器有限公司|Refrigerator having energy storage function|

DE102010063057A1|2010-12-14|2012-06-14|Robert Bosch Gmbh|Battery system for a motor vehicle with at least one electrochemical cell and at least one latent heat storage|

US9624022B2|2011-04-08|2017-04-18|Sharp Kabushiki Kaisha|Storage container utilizing two different heat insulating materials in combination with a temperature control unit and a heat storage material placed within the container|

US8887515B2|2012-08-23|2014-11-18|Pelican Biopharma, Llc|Thermal management systems and methods|

JP6054740B2|2012-12-27|2016-12-27|トッパン・フォームズ株式会社|Constant temperature storage tool and storage container containing the same|

US9267722B2|2013-05-10|2016-02-23|Packaging Technology Group, Inc.|Phase change material bladder for use in a temperature controlled product shipper|

GB201318405D0|2013-10-17|2013-12-04|Gray David|A portable temperature controlled container|

US20180266746A1|2015-05-29|2018-09-20|Sharp Kabushiki Kaisha|Heat insulating container and method for producing same|SG11201809938QA|2017-01-18|2018-12-28|Fridge To Go Ltd|Mobile storage apparatus|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

ATA518/2015A|AT517516B1|2015-08-04|2015-08-04|Transport container for transporting temperature-sensitive cargo|ATA518/2015A| AT517516B1|2015-08-04|2015-08-04|Transport container for transporting temperature-sensitive cargo|

EP16450012.6A| EP3128268A1|2015-08-04|2016-06-14|Transport container for transporting temperature-sensitive products|

US15/224,249| US11060783B2|2015-08-04|2016-07-29|Transport container for transporting temperature-sensitive transport goods|

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