This disclosure relates to a method and container for shipping a frozen food product, normally in the form of an uncooked fruit pie, with a decorative container for holding the food product such that the decorative container is adjacent to the frozen food product which in turn is positioned adjacent to a refrigeration component to maintain the frozen product frozen during shipment. The combination provides an unusual gifting opportunity providing a reusable laser engraved commemorative and reusable memorabilia for celebrating life's important events. Preferably the food product is uncooked and is conventionally baked by the recipient or by another prior to presentation to the intended recipient.

Insulation container for the temperature-controlled transport of pharmaceutical products, comprising an outer container with an outer container base and an outer container wall, which are connected to one another in such a way as to form a receiving space open on one side, and wherein the insulation container comprises a lid which is designed to completely cover the receiving space by placing the lid on the outer container, and wherein the insulation container furthermore has a receiving space comprises inserted compartment which separates the receiving space into separate compartments.

The present invention relates to the transport of products in a desired conservation temperature range, comprising: a box (2) made of insulating material delimiting a compartment opened upwards having a volume less than 150 liters and able to contain products, the box (2) having a determined heat dissipation value; a cover (4) made of insulating material adaptable on the box (2) to seal the compartment; a diffusing divider wall (5) interposed between the box (2) and the cover (4) to delimit with the cover (4), a chamber with a surface (7) for receiving at least one refrigerated load (6) emitting a heat value, the cover (4) and the divider wall (5) comprising complementary means for locking/unlocking (9) with one another; characterized in that the heat energy emitted by the refrigerated load (6) and the thermal diffusion coefficient of the divider wall (5) are adjusted such that, at determined transport and conservation temperatures and for a desired duration after receiving the refrigerated load (6) and exposure of the container (1) to the transport temperature, the heat value diffused by the divider wall (5) to the compartment is equal to, or at most 20% greater than the heat value dissipated by the box (2).

The present invention relates to the transport of products in a desired conservation temperature range, comprising: a box (2) made of insulating material delimiting a compartment opened upwards having a volume less than 150 liters and able to contain products, the box (2) having a determined heat dissipation value; a cover (4) made of insulating material adaptable on the box (2) to seal the compartment; a diffusing divider wall (5) interposed between the box (2) and the cover (4) to delimit with the cover (4), a chamber with a surface (7) for receiving at least one refrigerated load (6) emitting a heat value, the cover (4) and the divider wall (5) comprising complementary means for locking/unlocking (9) with one another; characterized in that the heat energy emitted by the refrigerated load (6) and the thermal diffusion coefficient of the divider wall (5) are adjusted such that, at determined transport and conservation temperatures and for a desired duration after receiving the refrigerated load (6) and exposure of the container (1) to the transport temperature, the heat value diffused by the divider wall (5) to the compartment is equal to, or at most 20% greater than the heat value dissipated by the box (2).

The invention provides a compact and self-sustained refrigeration system for medical uses, including in hospitals, in clinics and in home uses, including rescue and field emergency situations, independent of external power supply, based on small amounts of liquid carbon dioxide.

Shipping system for storing and/or transporting temperature-sensitive materials. In one embodiment, the system includes an outer box having four side walls, bottom closure flaps, and top closure flaps. A vacuum insulated panel (VIP) is detachably coupled to one of the top closure flaps and is removably covered by a cover. An insulation unit is removably positioned within the outer box, the insulation unit including a plurality of VIPs arranged to define a cavity bounded by a bottom wall and four side walls. A disposable liner assembly is removably mounted on the insulation unit. The liner assembly includes a first liner piece, a second liner piece, and a liner support. A plurality of temperature-control members and a product box may be removably positioned in a cavity defined by the liner assembly. The temperature-control members snugly fit around all sides of the product box and each include a container containing dry ice.

Shipping system for storing and/or transporting temperature-sensitive materials. In one embodiment, the system includes an outer box having four side walls, bottom closure flaps, and top closure flaps. A vacuum insulated panel (VIP) is detachably coupled to one of the top closure flaps and is removably covered by a cover. An insulation unit is removably positioned within the outer box, the insulation unit including a plurality of VIPs arranged to define a cavity bounded by a bottom wall and four side walls. A disposable liner assembly is removably mounted on the insulation unit. The liner assembly includes a first liner piece, a second liner piece, and a liner support. A plurality of temperature-control members and a product box may be removably positioned in a cavity defined by the liner assembly. The temperature-control members snugly fit around all sides of the product box and each include a container containing dry ice.

A modular box assembly includes a box, the box defining a top end and a bottom end disposed opposite from the top end, the box including a plurality of side panels extending between the top end and the bottom end, the plurality of side panels at least partially defining a box cavity within the box; and an inner box positioned within the box cavity, the inner box dividing the box cavity into a first sub-compartment and a second sub-compartment, the inner box including a channel tab extending outward from a side panel of the inner box, the channel tab engaging a first side panel of the plurality of side panels of the box.

A device for cooling or freezing glasses with carbon dioxide, having an upwardly open inner space for receiving a glass, wherein the inner space is enclosed all around by an inner wall, wherein a nozzle and a support tray are arranged in the inner space and a glass to be cooled or frozen is movable into the inner space and against the support tray from above, whereby carbon dioxide is released into the glass from the nozzle, and wherein the device has an outer wall, wherein the inner wall has openings leading into the device interior between the inner wall and the outer wall, and/or the inner wall is open towards the device interior beneath the support tray or is sealed with an inner bottom element which has multiple openings leading into the device interior. Optional elements allow fastening the device directly to the valve cap of a gas cylinder.

A modular box assembly includes a box with side panels defining a box cavity, a first thermal liner positioned within the box cavity, the first thermal liner including a first insulation batt disposed between sheets, the first thermal liner defining three first liner panels, at least one box side panel being covered by a first liner panel, and a second thermal liner positioned within the box cavity, the second thermal liner including a second insulation batt disposed between sheets, the second thermal liner defining three second liner panels. At least one other of the side box panels is covered by a second liner panel. The bottom box panel is covered by either a first liner panel not covering any side box panel or a second liner panel not covering any side box panel. Each insulation batt can be formed from a mixture of thermoplastic binder fibers and reinforcement fibers.