A temperature regulated apparatus can include a layered member comprising a first layer of material and a second layer of material connected to the first layer. The layered member can have a first opening formed therein and an interior area defined by the first layer and the second layer. The interior area can be in communication with the first opening. A temperature regulating element adapted to alter the temperature of the layered member can be positioned within the interior area of the layered member, and can be removed from the layered member without disassembling the layered member.

Disclosed is a technique for characterizing a product utilizing novel measurements based on the reactive and resistive signals exhibited by the product in an electromagnetic field.

A cooler is provided which has various improvements. The cooler may be a passive cooler or may be actively cooled for providing desirable cooling effects. The cooler may include an accessory system, for example, with bottle or can holders or a post holder which utilizes the weight of the cooler to support a sunshade. The accessory system may be positioned in various locations of the cooler, one location being in a recess which is utilized to open the cooler lid. The smart cooler may also comprise a cushion assembly which may be placed on an upper surface of the lid and may have straps to retain the cushion on the lid. The lid may be formed to accept and retain a cushion retaining feature so that the cushion does not excessively move from the top surface of the lid.

A cooler is provided which has various improvements. The cooler may be a passive cooler or may be actively cooled for providing desirable cooling effects. The cooler may include an accessory system, for example, with bottle or can holders or a post holder which utilizes the weight of the cooler to support a sunshade. The accessory system may be positioned in various locations of the cooler, one location being in a recess which is utilized to open the cooler lid. The smart cooler may also comprise a cushion assembly which may be placed on an upper surface of the lid and may have straps to retain the cushion on the lid. The lid may be formed to accept and retain a cushion retaining feature so that the cushion does not excessively move from the top surface of the lid.

Variable temperature analytical assemblies are provided and/or methods for changing temperatures of a mass are provided. Low thermal conductance components and/or assemblies are also provided. Methods for thermally isolating a mass from a support structure are also provided.

A portable insulated container includes an outer shell and a temperature control pack. The portable insulated container also includes a first insert portion that fits inside the outer shell and a second insert portion that also fits inside the outer shell and is configured to engage with the first insert portion to form a plurality of insulated cavities including a temperature control pack cavity along with three or more separate bottle storage cavities. Each of the three or more bottle storage cavities is configured for receiving a bottle and each of the three or more bottle storage cavities is configured for receiving bottles of different sizes and shapes. Each of the three or more bottle storage cavities may also be equidistant from the temperature control pack cavity.

A portable insulated container includes an outer shell and a temperature control pack. The portable insulated container also includes a first insert portion that fits inside the outer shell and a second insert portion that also fits inside the outer shell and is configured to engage with the first insert portion to form a plurality of insulated cavities including a temperature control pack cavity along with three or more separate bottle storage cavities. Each of the three or more bottle storage cavities is configured for receiving a bottle and each of the three or more bottle storage cavities is configured for receiving bottles of different sizes and shapes. Each of the three or more bottle storage cavities may also be equidistant from the temperature control pack cavity.

An system and method for cooling of electronic equipment, for example a computer system, in a subsurface environment including a containment vessel in at least partial contact with subsurface liquid or solid material. The containment vessel may be disposed in a variety of subsurface environments, including boreholes, man-made excavations, subterranean caves, as well as ponds, lakes, reservoirs, oceans, or other bodies of water. The containment vessel may be installed with a subsurface configuration allowing for human access for maintenance and modification. Cooling is achieved by one or more fluids circulating inside and/or outside the containment vessel, with a variety of configurations of electronic devices disposed within the containment vessel. The circulating fluid(s) may be cooled in place by thermal conduction or by active transfer of the fluid(s) out of the containment vessel to an external heat exchange mechanism, then back into the containment vessel.

A rapid cooling system for processing food is disclosed which includes a heat exchanger adapted to receive a first coolant (Coolant-I) at a first temperature and eject Coolant-I at a second temperature, a cooling chamber disposed within the heat exchanger in thermal communication with the heat exchanger, the cooling chamber includes a first inlet adapted to receive a product at an elevated temperature (T1), a second inlet adapted to receive a second coolant (Coolant-II) at a low temperature (T2), and an outlet adapted to release a combination of the product and Coolant-II at a low temperature (T.sub.out) and pressure (P.sub.out), wherein cooling of the product from T1 to T.sub.out does not cause a phase change in the product.

A rapid cooling system for processing food is disclosed which includes a heat exchanger adapted to receive a first coolant (Coolant-I) at a first temperature and eject Coolant-I at a second temperature, a cooling chamber disposed within the heat exchanger in thermal communication with the heat exchanger, the cooling chamber includes a first inlet adapted to receive a product at an elevated temperature (T1), a second inlet adapted to receive a second coolant (Coolant-II) at a low temperature (T2), and an outlet adapted to release a combination of the product and Coolant-II at a low temperature (T.sub.out) and pressure (P.sub.out), wherein cooling of the product from T1 to T.sub.out does not cause a phase change in the product.