Source: https://patents.google.com/patent/RU2347157C2/en
Timestamp: 2020-02-21 05:25:36
Document Index: 674676541

Matched Legal Cases: ['arts 13', 'art 15', 'arts 13', 'arts 12', 'arts 12', 'arts 13', 'arts 12', 'arts 13', 'arts 12', 'art 15', 'arts 13', 'art.\n3']

RU2347157C2 - Insulated transportation containers - Google Patents
Insulated transportation containers Download PDF
RU2347157C2
RU2347157C2 RU2006103357/12A RU2006103357A RU2347157C2 RU 2347157 C2 RU2347157 C2 RU 2347157C2 RU 2006103357/12 A RU2006103357/12 A RU 2006103357/12A RU 2006103357 A RU2006103357 A RU 2006103357A RU 2347157 C2 RU2347157 C2 RU 2347157C2
RU2006103357/12A
RU2006103357A (en
Родни М. ДЭРИФИЛД (US)
Родни М. ДЭРИФИЛД
2003-07-07 Priority to US48548403P priority Critical
2003-07-07 Priority to US60/485,484 priority
2004-07-07 Application filed by Родни М. ДЭРИФИЛД filed Critical Родни М. ДЭРИФИЛД
2006-06-10 Publication of RU2006103357A publication Critical patent/RU2006103357A/en
2009-02-20 Publication of RU2347157C2 publication Critical patent/RU2347157C2/en
FIELD: transportation; transportation of goods.
SUBSTANCE: proposed container for holding temperature sensitive products and a coolant in a given ratio for maintaining cooling or freezing conditions for a long period of time has a container, which has a base, four walls and an upper part. The base supports the temperature sensitive products, and the tray of the coolant, which can be put inside the container over the product, and can also be removed, and comprises a central, pre-formed conducting unit. The tray is made such that, coolant packets can be put on it, around the conducting unit.
EFFECT: better conditions of transporting temperature sensitive products in cooled and/or frozen state for a long period of time.
This invention relates to shipping containers, in particular to insulated shipping containers for holding temperature-sensitive products and refrigerant in a predetermined ratio to maintain cooling or freezing conditions for a long period of time. For example, containers of this type are formed from rigid polyurethane foam or other materials for transportation or transportation of products, such as biological or similar products, which must be stored at a temperature of 2 ° C to 8 ° C or frozen.
Various types of shipping containers have been developed, including conventional cardboard boxes having insulating material inside that can be molded to the desired shape or that contains panels or the like. Typically, a refrigerant such as packaged ice, gel packs, or loose solid ice is placed in a cavity around the product to cool the product during transportation.
For transporting particularly sensitive products, such as medical or pharmaceutical products, rigid polyurethane containers are often used due to their thermal properties. Conventional insulated shipping containers have many drawbacks, in particular when transporting temperature-sensitive products for a long period of time, for example during international transport of products. These containers, especially for modular systems, often include a large number of joints in the insulating material through which air can pass and heat up the cavity in the box. In addition, the cavity often contains air spaces around the product and refrigerant, which can facilitate, but not in a controlled manner, convection, especially if the insulating material includes leaky joints. Unfortunately, gradients or temperature zones are created. These conditions can accelerate the melting of the refrigerant, and, accordingly, shorten the time during which the container can maintain the cooling conditions. In addition, the lid may be made of another material, such as polyester foam, which may have a thermal resistance much lower than the body itself, and thereby may degrade the performance of the container.
In addition, the product and the refrigerant are usually placed together inside the cavity in the box, which may have a negative effect. When transporting some products, it is advisable to cool them, but not freeze the product. Placing a refrigerant, such as blocks of dry ice, in a cavity in contact with the product can cause the product to freeze and spoil. Even if the refrigerant is kept at a distance from the product, then during transportation the refrigerant can be displaced in the cavity, in particular, when it melts and decreases in volume and inadvertently comes into contact with the product. In addition, molten refrigerant may leak out of its container, causing a mess in the cavity or even contaminating the product being transported.
Some suitable solutions to the above disadvantages have been developed in the past, such as disclosed in US patent No. 5924302. However, there is still a need for containers, in particular for transporting large quantities of an article for a long time.
The aim of the present invention is to provide new and improved containers for transporting temperature-sensitive products in a refrigerated and / or frozen state over a long period of time.
According to the present invention, a description and drawings of several embodiments of containers, for example, of rigid polyurethane foam, which are particularly suitable, inter alia, for small and large shipments, such as air shipments, including the use of LD3 shipping containers, are provided. It is important that the containers according to this invention are formed mainly from the bottom, preferably with a pallet for holding the product, four sides and a lid, and also preferably with a refrigerant tray. In addition, the bottom, sides and cover are interconnected (the sides and the base are preferably fixed with a bayonet or stud connection, as opposed to the usual 45 ° angles that are not fixed and do not interlock with each other) to reduce thermal convection . In addition, rigid polyurethane foam is formed with the formation of the bottom of the container and can have “rack” grooves, in contrast to the use of wood, which can cause problems with termites, in particular, in the conditions of air cargo transportation. The refrigerant tray is preferably a retractable tray that contains a suitable refrigerant, such as dry ice or gel packs, and which is also preferably made of rigid polyurethane foam so that the refrigerant does not come into direct contact with the product. In addition, the inner walls and the bottom of the container can be provided with convection to create a controlled air flow inside the compartment for the product, and this air flow can reduce the temperature gradient inside the compartment for the product and thereby provide better and more uniform temperature control during transportation of biological and other products.
Thus, according to the present invention, the containers may comprise gripping walls, in particular in larger containers, in order to reduce thermal convection between the external environment and the internal space. The refrigerant drawer can be of any different shape and / or shape and is used to control the temperature between the refrigerant and the product. The inner walls of the sides, the bottom and the lid are preferably configured to provide convection and thereby create a controlled air flow inside the compartment for the product in order to control and reduce the temperature gradient inside the compartment for the product, and thereby provide better control when transporting biological and other products. For example, on the walls, bottom and cover, for example, grooves and / or protrusions formed in them to provide convection and thereby cooling air flow around the product can be made. In addition, the side walls may have a shape, such as a V-shape or U-shape, or any variation thereof, to provide “convection walls” on two sides and cooling on two other sides. In addition, the refrigerant tray may include a central column formed in the tray to maintain a cooling effect in the center of the load of the product. Thus, the containers according to this invention provide control of convection of heat through a given air flow using the design of the sides, grooves, etc. in order to minimize the temperature gradient in the loaded product and to maintain the same temperature in the corners, middle and in all areas of the loaded product. The gripping joints between the sides and the base help control heat conduction and convection from the outside into the container. The base is made with the possibility of holding the loaded product at a distance from the actual bottom of the container and is equipped with air channels to ensure circulation of internal air around the entire payload. The base for large containers is preferably configured to transport pallets loaded with products, such as biological products.
figure 1 - a large insulating container according to this invention;
figure 2 - container, according to figure 1 in exploded isometric view;
figa - partially assembled container according to figure 1 in an exploded isometric view;
figv-D - components of the container according figa;
4 is an open top of the container and a refrigerant tray having a conductive block and gel packs;
5A-5E are a container assembly similar to the container of FIG. 1 for assembling a container around a cryogenic reservoir;
figa-6C is a container with V-shaped sides and grooves to facilitate the circulation of cold air around the loaded product to be located in the middle of the container;
Fig.7 is another embodiment of the container in isometric view.
Figure 1 shows an embodiment of an insulating container 10 according to this invention. It is preferably made of a base - water rigid polyurethane foam with sides 12, front and rear parts 13, bottom 14 and a cover or upper part 15, all made with the possibility of interconnection with each other for ease of storage and assembly, as well as to reduce convection.
As shown in FIG. 2, a temperature range, for example, from 0 ° C. to 10 ° C., can be maintained by using the upper ice tray 16 to hold the necessary refrigerant 17 for the product load 18 in the container. The pallet 16 can preferably be moved inward over the load 18 of the product. An inner pallet 20 for the product with upwardly extending sides 20a can be installed to isolate the bottom of the load 18 of the product from the bottom or base 14 and reduce the temperature gradient inside the container. The base 14 may comprise elevator fork grooves formed in the base to eliminate the need for a separate wood pallet. It is advisable to exclude wooden pallets or other wooden components due to termite problems in air freight and other conditions. The container shown in FIG. 1 may be of any desired size according to the LD3 standard for shipping containers in order to optimize the payload.
2 and 3A-3D show the relationship structure of the sides, rear, front, upper and lower parts to provide an interconnected structure of the container 10 according to this invention. The sides 12 have tongues 12a at their upper end, vertical elongated grooves 12b on the outer edges of the inner side, and a groove 12c at the bottom, as shown in FIGS. 2 and 3A-3B. On the other hand, the rear and front parts have upper and lower tongues 13a and side tongues 13b, as shown in FIG. The rear and front parts 13 are joined to the side parts 12 by means of tongues 13b of the rear and front parts included in the corresponding elongated grooves 12b in the side parts 12. This allows the rear and front parts 13 to easily slide into the grooves 12b of the side parts 12 to form a very tight and rigid structure of the front, rear and side parts, the relationship of the three components of which is shown in figa (the front part has not yet been added). The base 14 has elongated grooves a for receiving the lower tongues 13a of the front and rear parts 13, as well as elongated tongues 14b for connecting with the lower grooves 12 from the side parts 12. The cover or upper part 15 has elongated grooves 15a (see fig.3D) for receiving the tongues 12a of the side portions 12 and the tongues 13a of the rear and front parts 13. This tongue and groove design is especially important to provide “gripping walls” to reduce thermal convection between the outer environment and the interior of the container 10. It provides good engagement mosvyaz four sides of the base and the lid when you build.
It is important that the refrigerant 17 is not in direct contact with the load 18 of the product. A retractable refrigerant tray 16 provides this insulation or buffer function, and grooves 12d in the side portions, grooves 13d in the rear and front portions 13 provide a predetermined downward flow of air in the side grooves around the loaded product through thermal convection to minimize the temperature gradient inside the product load. Similar grooves 16b in the refrigerant tray 16 also contribute to this. In addition, similar grooves can be made in the base 14 or, if desired, in the pallet 20 for the product.
It is important that a column 16a is provided in the center of the drawer 16, which extends upward, as shown in FIGS. 2 and 4, and which is especially important from the point of view of thermal conductivity to reduce the conductivity of the refrigerant down to the center of the load 18 of the product that could occur the location of the refrigerant 17 in place of the column 16A. It has been found that without column 16a, the center of the load 18 of the product becomes too cold and that this foam column 16a reduces the temperature of the usually too cold center of the load to facilitate maintaining a uniform temperature of the product. Inside the refrigerant tray 16, spacers 16c are preferably provided for holding ice packs 17 in place. In addition, these spacers 16c may have through holes to allow free passage of air inside the ice pack 17. This arrangement and design increase the thermal efficiency of the ice pack.
On figa-5E shows the Assembly of the container, starting with the base 42, which is loaded with the tank 40 with the product, as shown in figa. Four inner walls 46 are inserted into the base 42, and then four female outer walls 48a are inserted into the base (see FIG. 5B), and then a pair of male external walls 48b (see FIG. 5C). The outer walls, base and top may be a structure with grooves and dowels, as in the previous figures. The space 44 between the inner walls 46 and the outer walls 48 is filled with granules of dry ice (not shown). A structure with tongues and grooves similar to the one above is used. Then, a thick, for example, 4 inch (10 cm) thick foam-cut pillow 50 is inserted into the outer walls 48 (see Fig. 5D) into the cavity of the product to reduce the tendency of the high product to bend and fall, and then fit the tightly fitting cover 52 (see Fig. .5E). A container made in this way is preferably inserted into a corrugated cardboard box and closed with adhesive tape.
On figa-6C shows another embodiment of a container made of rigid polyurethane foam, made with the possibility of creating an air flow inside the compartment for the product in order to reduce the temperature gradient inside the compartment for the product and thereby better control during transportation of biological products. This embodiment includes, as shown in FIG. 6, the right and left sides 80 and the front and rear sides 82, as well as the base or bottom 83. Of particular importance in this container design are the inner right and left side walls 86, which in this embodiment the executions are V-shaped, but may be U-shaped, provided with channels or having another suitable curved configuration. This provides air space between these inner side walls 86 and a stack of product (not shown) located in a cavity formed between the inner walls 86 and vertically mounted barriers 88 that create air currents. The inner sides of the front and rear walls 82, together with the outer sides of the barriers 88, form cooling cavities 90 for the refrigerant, which is usually ice gel. The barriers 88 may be spaced apart from each other, as shown in FIG. 6A, or may each be a solid wall. The base 83 has raised zones 84a defining grooves 84b between the zones 84a to provide some air space at the base. The combination of V-shaped inner walls 86, grooves 84b in the bottom and similar grooves in the lid, if desired (not shown), provides a flow of cold air due to convection inside the compartment 92 for the product. As in other embodiments, the container shown in FIG. 6 is preferably made of rigid polyurethane foam.
The embodiment shown in FIG. 6A has a relatively large product compartment 92, and the embodiment shown in FIG. 6B has a smaller product compartment 92a, however, the V-shaped wall and groove design are similar. Raised zones 84a are provided, forming grooves 84b, as shown in FIG. 6A, with the embodiment shown in FIG. 6C similar to the embodiment shown in FIG. 6A, but further comprises a retractable product tray 96. In the embodiments shown in FIG. 6, walls, a base and a top with tongues and grooves can be used, if desired.
7 shows another embodiment, in particular for use with a product container having a lid on top. The entire container 100 is similar to other embodiments and includes a lower cushion 102 and a lid 106. The foam tray 104 made of foam is adapted to be mounted on the lid of the product container to provide a stable insulating barrier. The side zones 104a and 104b form refrigerant trays (not shown) on each side of the upstream central portion 104c. The pallet 104 also has slots 104d to improve airflow. The central portion 104c is a conductive block similar to the block 16a in FIG. 4 for controlling the temperature in the central portion. The walls, base and top can also be constructed with tongues and grooves.
Thus, an improved shipping container has been described to maintain a cooling or freezing condition for a long period of time for the article contained therein. Important features are, in particular, the retractable ice tray 16 (for refrigerant 17), which can be moved into the container after placing the load 18 of the product. Another particularly important feature is the interconnected walls, cover and base for controlling thermal convection between the external environment and the internal atmosphere. Another important feature is the given shape, cavities and channels at various places in the container for using thermal convection to move and distribute energy more evenly within the container. This also ensures maximum energy return by the refrigerant, and also reduces the temperature gradients inside the container’s internal atmosphere. In addition, a preformed unit is provided to reduce temperature pockets inside the container by protecting specific locations within the container from direct contact with the refrigerant, in particular the center. This barrier uses the properties of thermal conductivity to consume energy from the cooling source until it reaches the load of the product. The pre-molded shape and size of the barrier can be selected to ensure that only the desired amount of energy passes, while maintaining stability and constancy during transportation.
Various changes, modifications, variations, as well as other uses and applications of the subject matter, may become apparent to specialists in this field of technology after reading this description and the accompanying drawings. All these changes, modifications, variations, as well as other uses and applications of the subject of the invention, which do not go beyond the idea and scope of the invention, are included in its scope of protection and are limited only by the following claims.
1. A shipping container for holding temperature-sensitive products and refrigerant in a predetermined ratio to maintain cooling or freezing conditions for a long period of time, containing a container having a base, four walls and an upper part, while the base provides support for the temperature-sensitive product, and a refrigerant tray configured to be located inside the container above the product, as well as removable, including a central, pre-formed nny conductive block, said tray adapted to receive thereon coolant packages around a conductive block.
2. The container according to claim 1, in which four walls are mutually connected to each other and additionally connected to the base and the upper part.
3. The container according to claim 2, in which the walls, bottom and top are mutually connected to each other through a system of tongues and grooves.
4. The container according to claim 1, in which at least one inner surface has grooves and / or protrusions for providing a predetermined air flow around the product through thermal convection to minimize the temperature gradient inside the load of the product.
5. The container according to claim 1, in which the walls, bottom and top are made of rigid polyurethane foam.
6. The container according to claim 1, containing four inner walls located inside the container and surrounding the product and providing air space between the walls of the container and these inner walls.
7. A shipping container for holding temperature-sensitive products and refrigerant in a predetermined ratio to maintain cooling or freezing conditions for a long period of time, containing a container having a base, four walls and an upper part, while the base provides support for the temperature-sensitive product, and in which four walls are mutually connected to each other and additionally connected to the base and the upper part, while on the inner surfaces of the walls are made vertical grooves for providing a predetermined air flow in them around the product through thermal convection to minimize the temperature gradient inside the product cargo, and a refrigerant tray made with the possibility of removal, as well as with the possibility of placing inside the container above the product and placing refrigerant packets on it, while the tray for the refrigerant, includes a central, preformed conductive unit for placing refrigerant packages thereon around the conductive unit.
8. A shipping container for holding temperature-sensitive products and refrigerant in a predetermined ratio to maintain cooling or freezing conditions for a long period of time, containing a container having a base, four walls and an upper part, while the base provides support for the temperature-sensitive product, and a refrigerant tray configured to be located inside the container above the product and including a central, pre-formed conductive unit for controlling eniya temperature in the central zone of the container and for placing refrigerant packets around the conductive block.
9. The container of claim 8, in which four walls are mutually connected to each other and additionally connected to the base and the upper part through a system of tongues and grooves.
10. The container of claim 8, in which at least one inner surface of the grooves are made to provide a given air flow around the product through thermal convection to minimize the temperature gradient inside the load of the product.
11. The container of claim 8, in which the walls, bottom and top are made of rigid polyurethane foam.
12. The container of claim 8, containing four inner walls located inside the container and surrounding the product to provide air space between the walls of the container and these inner walls.
13. The container according to claim 1, in which the two opposite walls have an internal V-shape to facilitate thermal convection inside the container and around the product.
14. The container of claim 8, in which two opposite walls have an internal V-shaped or U-shaped to facilitate thermal convection inside the container and around the product.
15. The container according to claim 1, in which on the basis of the lower grooves for fork fork.
16. The container according to claim 1, in which the ice tray is made with the possibility of installation on the lid of the container for the product to provide a stable insulating barrier.
17. A transport container for holding temperature-sensitive products and refrigerant in a predetermined ratio to maintain cooling or freezing conditions for a long period of time, containing a container having a base, four walls and an upper part, while the base is capable of supporting the temperature-sensitive product and four walls are mutually connected with each other and mutually connected with the base and the upper part, four inner walls located inside the container and surrounding Cereal to provide air space between the container walls and these inner walls, a pillow, which is incorporated in the external walls in the product cavity to minimize its tilting, and the refrigerant between the outer and inner walls.
18. A shipping container for holding temperature-sensitive products and refrigerant in a predetermined ratio to maintain cooling or freezing conditions for a long period of time, containing a container having a base, four walls and an upper part, while the base provides support for the temperature-sensitive product, and in which one or more internal surfaces include grooves to provide a given airflow into them around the product through thermal convection to minimize temperature dIntent inside the product load, and two opposite walls have an internal V-shaped or U-shape to facilitate thermal convection inside the container and around the product, while in the two other opposite walls there are cooling cavities for accommodating refrigerant packets and a refrigerant tray made with the possibility of removal, as well as the location inside the container above the product and placing refrigerant packets on it, while the refrigerant tray includes a central, pre-formed outgoing block.
RU2006103357/12A 2003-07-07 2004-07-07 Insulated transportation containers RU2347157C2 (en)
US48548403P true 2003-07-07 2003-07-07
RU2006103357A RU2006103357A (en) 2006-06-10
RU2347157C2 true RU2347157C2 (en) 2009-02-20
RU2006103357/12A RU2347157C2 (en) 2003-07-07 2004-07-07 Insulated transportation containers
AU (1) AU2004257250B2 (en)
BR (1) BRPI0412300A (en)
MX (1) MXPA06000301A (en)
NZ (1) NZ544134A (en)
WO (1) WO2005007519A2 (en)
RU2347157C2 (en) * 2003-07-07 2009-02-20 Родни М. ДЭРИФИЛД Insulated transportation containers
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2004-07-07 RU RU2006103357/12A patent/RU2347157C2/en not_active IP Right Cessation
2004-07-07 AU AU2004257250A patent/AU2004257250B2/en not_active Ceased
2004-07-07 EP EP20040756876 patent/EP1654506A2/en not_active Withdrawn
2004-07-07 CN CN 200480019195 patent/CN100549578C/en not_active IP Right Cessation
2004-07-07 US US10/886,310 patent/US7028504B2/en not_active Expired - Fee Related
2004-07-07 CA CA 2531583 patent/CA2531583C/en not_active Expired - Fee Related
2004-07-07 WO PCT/US2004/022199 patent/WO2005007519A2/en active Application Filing
2004-07-07 NZ NZ54413404A patent/NZ544134A/en not_active IP Right Cessation
2004-07-07 MX MXPA06000301A patent/MXPA06000301A/en active IP Right Grant
2004-07-07 BR BRPI0412300 patent/BRPI0412300A/en not_active IP Right Cessation
2004-07-07 JP JP2006518954A patent/JP4491613B2/en not_active Expired - Fee Related
2005-11-18 US US11/283,155 patent/US7225632B2/en active Active
2007-04-24 US US11/739,564 patent/US20070193298A1/en not_active Abandoned
JP4491613B2 (en) 2010-06-30
JP2007523803A (en) 2007-08-23
US20050006272A1 (en) 2005-01-13
CA2531583A1 (en) 2005-01-27
BRPI0412300A (en) 2006-06-13
AU2004257250B2 (en) 2010-07-15
WO2005007519A2 (en) 2005-01-27
CA2531583C (en) 2011-08-23
MXPA06000301A (en) 2006-07-03
AU2004257250A1 (en) 2005-01-27
US7225632B2 (en) 2007-06-05
WO2005007519A3 (en) 2005-06-09
NZ544134A (en) 2009-01-31
CN100549578C (en) 2009-10-14
US20060065009A1 (en) 2006-03-30
RU2006103357A (en) 2006-06-10
US7028504B2 (en) 2006-04-18
CN1836137A (en) 2006-09-20
EP1654506A2 (en) 2006-05-10
US20070193298A1 (en) 2007-08-23
US4964283A (en) 1990-10-23 Isothermal container with reservoir for refrigerant and its use for the transportation of fresh products
2010-02-10 PC4A Invention patent assignment