The present invention relates to a device that can be used for heating and/or refrigerating and/or maintaining the temperature of a receptacle. According to the invention, characteristically it comprises a base module which comprises: heat-producing means (5) and cold-producing means (7), said cold producing means comprising a reservoir (7) containing a fluid and possibly connected to an evaporator, said heat-producing means comprise a thermochemical reactor (5) connected to said reservoir (7) and containing a reagent able to react reversibly with said fluid during an exothermal reaction:—means forming a valve that allows said reservoir (7) or said evaporator to be connected to said thermochemical reactor (5) to produce heat in said reactor (5) as a result of said aforementioned exothermal reaction and simultaneously to produce cold in said reservoir (7), as the result of the expansion and/or evaporation of said fluid;—at least one receptacle (3) made of a thermally conducting material which has a first face able to house the foodstuff that is to be heated/refrigerated and a second face, opposite to said first face and arranged in contact with said heat-producing means (5) or said cold-producing, means (7);—an insulating element (15) which thermally insulates said heat-producing means (5) from said cold-producing means (7); and said reactor (5) and/or said receptacle (3) are removably mounted on said base module.

The present invention provides a waterless keep-alive apparatus and a refrigeration appliance having the same. The waterless keep-alive apparatus is provided in an inner tank of a refrigeration appliance, and comprises: a keep-alive box allowing pulling inward and outward; a temperature controlling module and a humidity controlling module which are connected with the keep-alive box; and an air controlling module having an air hole provided on a side wall of the keep-alive box and an air duct fixed on the inner tank of the refrigeration appliance. The air duct is hermetically connected with the air hole when the keep-alive box is pushed into the inner tank of the refrigeration appliance. The air duct is disconnected from the air hole when the keep-alive box is pulled out. The waterless keep-alive apparatus realizes convenient article fetching while the oxygen concentration in the keep-alive box can meet the survival needs of aquatic products.

A method for controlling a refrigerating device of a water dispenser. The method includes: S1, controlling a refrigerating module to cool water in a cold water tank; S2, when the temperature of the water in the cold water tank is reduced to a first preset temperature, stopping the refrigerating module at the first preset time; S3, controlling the refrigerating module to work again to continue cooling the water in the cold water tank; S4, when the temperature of the water in the cold water tank is reduced to an n.sup.th preset temperature, stopping the refrigerating module at the n.sup.th preset time; and S5, determining whether the temperature of the water in the cold water tank reaches a target temperature, and if not, repeating steps S3 and S4 after reaching a predefined number. Through multi-stage refrigeration, an ultra-low temperature refrigeration is achieved.

An invention for rapid chilling or heating of both carbonated and non-carbonated fluids is disclosed. The invention is a fluid dispensing device that can rapidly cool or heat carbonated or non-carbonated liquid from room temperature to a desired temperature. The electric on-demand device allows pour-through and pump-through fluid dispensing and temperature control.

A beverage diluting and cooling container includes a floor, a peripheral sidewall, and a divider wall that divides an interior space defined by the peripheral sidewall into a first compartment that receives a cooling medium for cooling and diluting a beverage received into the first compartment. The divider wall also divides the interior space into a second compartment that holds a second quantity of a cooling medium for non-dilutingly cooling the beverage. The second compartment is sealed from the first compartment to prevent flow of liquid from the second compartment into the first compartment. One or more of the floor or a portion of the sidewall bounding the first compartment includes at least one opening therethrough to allow flow of the beverage out of the first compartment while containing the cooling medium in the first compartment.

A beverage diluting and cooling container includes a floor, a peripheral sidewall, and a divider wall that divides an interior space defined by the peripheral sidewall into a first compartment that receives a cooling medium for cooling and diluting a beverage received into the first compartment. The divider wall also divides the interior space into a second compartment that holds a second quantity of a cooling medium for non-dilutingly cooling the beverage. The second compartment is sealed from the first compartment to prevent flow of liquid from the second compartment into the first compartment. One or more of the floor or a portion of the sidewall bounding the first compartment includes at least one opening therethrough to allow flow of the beverage out of the first compartment while containing the cooling medium in the first compartment.

Disclosed is container for modifying temperature of an object on receiving commands from a computing device. The container includes a hollow outer vessel, a hollow inner vessel, a hollow cylindrical bracket, a first temperature sensor, a peltier element, a heat sink, a second temperature sensor, a battery, a printed circuit board, a memory unit, a microprocessor, a bi-directional communication unit, and a bottom cover. The hollow cylindrical bracket is having a first indent, a second indent, a sidewall, and a closed bottom end. The hollow bracket sidewalls move between the second outer surface and the first inner surface. The first temperature sensor measures temperature of the second outer surface of the inner vessel. The memory unit stores pre-defined reference temperature. The microprocessor processes signals received from the first temperature sensor and the second temperature sensor. The microprocessor regulates current and voltage for the peltier element depending upon the processed signals and the stored pre-defined reference temperature. The bi-directional communication unit communicates signals between the microprocessor and the computing device. The computing device sends command to the controller to regulate the temperature of the inner vessel. The bottom cover covers the battery and the printed circuit board. Further, the bottom cover attaches to the hollow bracket.

An ice chest system includes an ice chest and first, second, third, and fourth legs removably securable with the ice chest. The ice chest includes a top, a bottom, and first, second, third, and fourth sides defining an ice bin. First and second pins are mechanically connected with the first, second, third, and fourth sides at each end thereof. The first, second, third, and fourth legs each include a first surface having first and second engagement slots and a second surface having first and second engagement slots. Securing the first, second, third, and fourth legs with the ice chest includes engaging the first and second engagement slots of the first, second, third, and fourth legs with the first and second pins of the first, second, third, and fourth sides.

An entrance refrigerator includes a cabinet in which a storage compartment is formed. The bottom of the storage compartment includes a main floor and a sub floor lower than the main floor. The main floor is formed to be slanted downwardly toward the sub floor, such that condensed water falling on the main floor of the storage compartment flows toward the sub floor and is collected on the sub floor.

An apparatus for simultaneously heating a plurality of food products, comprising: a containment structure forming a housing chamber; one or more separating elements mounted in the housing chamber to delimit a plurality of separate housing compartments for receiving the food products; radio frequency dielectric heating means with an operating frequency of between 1 MHz and 300 MHz, mounted in the containment structure and comprising at least one first electrode and one second electrode; wherein the housing compartments are aligned along a row, the first electrode and the second electrode delimiting on two opposite sides the row; and wherein inside the housing chamber, between the first electrode and the second electrode , there is also at least one inductor.