A system is described herein for repurposing waste heat from a refrigeration cycle to improve the efficiency of the cycle and power electronic devices. The system may include a compressor, a turbine, an accumulator, a condenser, a throttle, and an evaporator. The accumulator may include a high-pressure chamber connected between the turbine and condenser, and a low-pressure chamber connected between the evaporator and the compressor. The high-pressure chamber may be segregated from the low-pressure chamber such that high-pressure refrigerant in the high-pressure chamber is prevented from mixing with low-pressure refrigerant in the low-pressure chamber. The high-pressure chamber and low-pressure chamber may be thermally coupled such that liquid refrigerant in the low-pressure chamber is vaporized by heat exchange with the high-pressure chamber. The turbine may power an electronic component of the refrigerator or may feed electricity back into a community grid power system.

A system is described herein for repurposing waste heat from a refrigeration cycle to improve the efficiency of the cycle and power electronic devices. The system may include a compressor, a turbine, an accumulator, a condenser, a throttle, and an evaporator. The accumulator may include a high-pressure chamber connected between the turbine and condenser, and a low-pressure chamber connected between the evaporator and the compressor. The high-pressure chamber may be segregated from the low-pressure chamber such that high-pressure refrigerant in the high-pressure chamber is prevented from mixing with low-pressure refrigerant in the low-pressure chamber. The high-pressure chamber and low-pressure chamber may be thermally coupled such that liquid refrigerant in the low-pressure chamber is vaporized by heat exchange with the high-pressure chamber. The turbine may power an electronic component of the refrigerator or may feed electricity back into a community grid power system.

A solar-powered two-bed adsorption chiller which can operate after sunset when the solar radiation intensity becomes zero. Rechargeable solar-powered batteries (SPBs) are connected to a flat-plate solar collector (FPSC). The photoelectric charges are directed from FPSC to a solar charge controller (SCC) which acts as a charge amplifier thus magnifying the total charge before it is finally collected inside the SPB for future use. The SPB is in turn connected to a resistance heating wire (RHW) which is immersed inside the HWST.

A transport refrigeration system includes a prime mover configured to power a refrigeration unit and a first fuel tank fluidly connected to prime mover through a first fuel line. The first fuel tank is configured to supply fuel to an inlet of prime mover from an outlet of first fuel tank through first fuel line. The transport refrigeration system also includes a first fuel flow sensor being an in-line flow meter and configured to measure a first fuel quantity exiting first fuel tank, a second fuel flow sensor being an in-line flow meter and configured to measure a second fuel quantity entering prime mover, a controller configured to compare second fuel quantity to first fuel quantity, and an alarm configured to activate when second fuel quantity is not equal to first fuel quantity.

A transport refrigeration system includes a prime mover configured to power a refrigeration unit and a first fuel tank fluidly connected to prime mover through a first fuel line. The first fuel tank is configured to supply fuel to an inlet of prime mover from an outlet of first fuel tank through first fuel line. The transport refrigeration system also includes a first fuel flow sensor being an in-line flow meter and configured to measure a first fuel quantity exiting first fuel tank, a second fuel flow sensor being an in-line flow meter and configured to measure a second fuel quantity entering prime mover, a controller configured to compare second fuel quantity to first fuel quantity, and an alarm configured to activate when second fuel quantity is not equal to first fuel quantity.

Various examples include a device for increasing the heat yield of a heat source comprising: a heat sink; a heat pump with a condenser and an evaporator; and the heat source. The heat sink includes a heat sink feed and a heat sink return providing thermal coupling to the heat source with a heat exchanger. The heat source includes a heat source feed and a heat source return for thermal coupling to the heat sink with the heat exchanger. The condenser of the heat pump is thermally coupled to the heat sink feed to dissipate heat to the heat sink. The evaporator of the heat pump is thermally coupled to the heat source return downstream of the heat exchanger to absorb heat.

A method and system for power supply integration, comprising interfacing at least one of: i) an AC power supply and ii) a DC power supply, and supplying, from the at least one of: i) an AC power supply and a ii) a DC power supply, DC power to the at least one DC load. The energy supply to the at least one DC load from the at least one AC power supply and the at least one DC power supply is controlled so as to selectively supply power from renewable energies for example.

A method and system for power supply integration, comprising interfacing at least one of: i) an AC power supply and ii) a DC power supply, and supplying, from the at least one of: i) an AC power supply and a ii) a DC power supply, DC power to the at least one DC load. The energy supply to the at least one DC load from the at least one AC power supply and the at least one DC power supply is controlled so as to selectively supply power from renewable energies for example.

An icemaking system includes a circulation circuit configured to circulate icemaking solution, at least one icemaker provided in the circulation circuit, a cooling mechanism, a first detector and an adjuster. The icemaker includes a cooling chamber and a scraping mechanism. The cooling chamber has an inflow port and an exhaust port of solution, and the cooling chamber allows the solution to flow in the cooling chamber. The scraping mechanism scrapes ice generated on an inner surface of the cooling chamber. The cooling mechanism cools the solution in the cooling chamber. The first detector detects whether the inflow port of the cooling chamber has an ice nucleus. The adjuster adjusts a cooling temperature of the solution in accordance with a detection result of the first detector.

A floating plate type marine refrigerated container system capable of generating electricity by using wave energy that relates to ocean energy, including a machine room, retractable pipes, vertical rise-fall pipes, vertical connecting rods, floating plates, controllers, a rising-falling control button, an indicator light, push-pull handles, grooves, fixed supports, generator sets, wires, a storage battery, a connecting block, a machine room door, a heat dissipation window, sliding areas, a movable plate, a displacement sensor, hinges, sliding shafts, sliding groove groups and the electrical equipment of the refrigerated container. The wave energy in the vertically moving waves is collected by the floating plate, and converted into electric energy. The electric energy are gathered to the storage battery, and finally supplied to the electrical equipment of the refrigerated container.