Temperature-controllable container with vacuum insulation elements and with an interior space, which container comprises a wall with an opening for objects to be placed into the interior space, and a door element closing the opening, wherein transport elements are arranged on an outer surface of the container, which transport elements are designed to enable lifting by means of a transport vehicle, and wherein the container further comprises a temperature control unit which is designed so as to bring the interior space to a predetermined temperature T, wherein the temperature control unit comprises a heating/cooling unit operated via a solar energy device or a heating/cooling unit operated via a power supply network, and wherein a receptacle means for melt-storage elements or sample bodies is arranged in the interior space, which receptacle means is designed so as to position at least two melt-storage elements or sample bodies at a distance from each other.

A cooler allows easy attachment and detachment of a battery. The cooler includes a main container including a refrigeration compartment, an evaporator on the main container, a compressor and a condenser adjacent to the main container, and at least one battery mount to receive a power tool battery in a detachable manner. The at least one battery mount is adjacent to the main container and above the compressor and the condenser.

The portable food storage and preparation device provides food storage and preparation facilities in a wheeled enclosure. The device has a portable power supply, a controller, a refrigerating module, a food heating module, and a beverage module. The refrigerating module is able to maintain food chilled either with chill packs or a refrigeration unit. The beverage module has a first water storage tank and a water heater, and water from the beverage module can be supplied to food being heated or cooked in the food heating module.

The portable food storage and preparation device provides food storage and preparation facilities in a wheeled enclosure. The device has a portable power supply, a controller, a refrigerating module, a food heating module, and a beverage module. The refrigerating module is able to maintain food chilled either with chill packs or a refrigeration unit. The beverage module has a first water storage tank and a water heater, and water from the beverage module can be supplied to food being heated or cooked in the food heating module.

The present application is directed to cooling containers that rely on refrigerants. The cooling container is able to efficiently keep items cool by adjusting the input and output of cool air inside the cooling container. For example, storage area no. 1 can keep the refrigerants used for keeping insulated items cool. Plank 1 is parallel to the storage area 1. Plank 2 is parallel to plank 1 and storage area no. 2 storing insulated items therein. The planks 1 and 2 are perpendicularly placed above and below a horizontal plane. Planks 1 and 2 can be adjusted to be higher or lower, so as to adjust the distance therebetween. This allows more efficient control of the airflow of the cool air before the air goes into storage area 2.

The present application is directed to cooling containers that rely on refrigerants. The cooling container is able to efficiently keep items cool by adjusting the input and output of cool air inside the cooling container. For example, storage area no. 1 can keep the refrigerants used for keeping insulated items cool. Plank 1 is parallel to the storage area 1. Plank 2 is parallel to plank 1 and storage area no. 2 storing insulated items therein. The planks 1 and 2 are perpendicularly placed above and below a horizontal plane. Planks 1 and 2 can be adjusted to be higher or lower, so as to adjust the distance therebetween. This allows more efficient control of the airflow of the cool air before the air goes into storage area 2.

A vacuum adiabatic body and a refrigerator are provided. The vacuum adiabatic body includes a support that maintains a vacuum space between a first plate and a second plate. The support includes a first support plate provided by coupling at least two partial plates to support one of the first plate or the second plate, and a second support plate that supports the other one of the first plate or the second plate.

A vacuum adiabatic body and a refrigerator are provided. The vacuum adiabatic body includes a support that maintains a vacuum space between a first plate and a second plate. The support includes a first support plate provided by coupling at least two partial plates to support one of the first plate or the second plate, and a second support plate that supports the other one of the first plate or the second plate.

A railcar backup cooling system may be added to an existing railcar (e.g., a boxcar) to provide supplemental or backup cooling to the railcar in the event that an HVAC failure or other circumstance occurs, which causes the interior temperature of the railcar to rise. The system includes a container of liquid or compressed gas mounted on the railcar, a valve controlling the flow of the liquid or gas from the container, and a controller configured to open the valve when the HVAC system fails or is otherwise unable to maintain the railcar at the desired temperature. When the valve is opened, the liquid and/or gas stored in the container may exit, expanding into a cool gas and thereby acting to cool the railcar environment.

An integrated air conditioning system having a first air conditioning unit having a first evaporator with a first input and a first output; a second air conditioning unit having a second evaporator with a second input and a second output; a first conduit fluidly connecting the first input with the second output; a second conduit fluidly connecting the second input with the first output. The first and second conduits and the first and second evaporators form a working fluid circuit.