Disclosed is a refrigeration system, which may include a generator, a condenser, an evaporator, and an absorber connected in sequence, the condenser being disposed above the evaporator, and the absorber being disposed below the evaporator; the evaporator includes an outer pipe, a hydrogen inlet pipe, and a liquid ammonia pipe; one end of the outer pipe is sealed and the other end thereof is connected to the absorber; the diameter of the end of the outer pipe connected to the absorber is gradually reduced facing a direction of the absorber; the hydrogen inlet pipe is hidden inside the outer pipe; an air outlet end of the hydrogen inlet pipe is disposed at the sealed end of the outer pipe.

A method for real-time detecting and dealing with ammonia leakage of a mini diffusion-absorption ammonia refrigerating apparatus used for refrigerators, wine cabinets or freezers comprising a main container body; the rear portion of the main container body is provided with a mini diffusion-absorption ammonia refrigerating apparatus; at least one high-sensitivity ammonia sensor is disposed in the refrigerating apparatus; the ammonia sensor is connected to a control panel; after detecting the concentration of ammonia gas, collecting and processing the data, many means can be initiated to prevent ammonia gas from being leaked, achieving a precise judgement and an effective treatment.

A method for real-time detecting and dealing with ammonia leakage of a mini diffusion-absorption ammonia refrigerating apparatus used for refrigerators, wine cabinets or freezers comprising a main container body; the rear portion of the main container body is provided with a mini diffusion-absorption ammonia refrigerating apparatus; at least one high-sensitivity ammonia sensor is disposed in the refrigerating apparatus; the ammonia sensor is connected to a control panel; after detecting the concentration of ammonia gas, collecting and processing the data, many means can be initiated to prevent ammonia gas from being leaked, achieving a precise judgement and an effective treatment.

A vehicle refrigerator is disclosed. The vehicle refrigerator may include a body, a refrigerating system and a driving system. The refrigerating system and the driving system are both arranged in the body. The body is removable in a trunk of a vehicle. The driving system is used for driving the refrigerating system to operate normally, and may include an igniter and an air source. The igniter is connected with the air source. The refrigerating system is used for cooling an inner cavity of the body and is provided with a working medium capable of changing gas and liquid.

A method and an arrangement for recovering heat from flue gas of a boiler (10). The method comprises passing the flue gas (G) of the boiler though a flue gas cooling unit (1), cooling the flue gas (G) by transferring heat from the flue gas (G) into a circulation (3) of a flue gas cooling liquid (CL), transferring heat energy of said flue gas cooling liquid (CL) into a heat pump (2), and arranging the heat pump (2) for receiving heat energy also from a circulation arrangement (8) of a district cooling system. The heat pump (2) is coupled to a circulation arrangement (6) of a district heating system, wherein the method further comprises transferring in the heat pump (2) heat energy (H) received from said cooling liquid (CL) and from said circulation arrangement (8) of district cooling system into said circulation arrangement (6) of district heating system, for lowering the temperature of said flue gas cooling liquid (CL) and cooling fluid of said district cooling system, and raising the temperature of heating fluid of said district heating system.

The present disclosure relates to an absorption cooling machine including an absorber, a first regenerator, a second regenerator, a condenser, an expansion device, and an evaporator, and relates to a cooling machine that connects a bypass collection pipe that guides an absorbent flowing back into the second regenerator to be collected into an absorber to a second collection pipe, in order to prevent the water level of the second regenerator from being raised as the absorbent cannot be collected by the absorber and flows back to the second regenerator, due to the pressure difference between an absorbent separated from the first regenerator and collected into the absorber through the first collection pipe, and an absorbent separated from the second regenerator and collected into the absorber through the second collection pipe.

A sorption heat pump, comprising a gaseous refrigerant; a liquid solvent; a lean solution and a rich solution, wherein the lean solution and the rich solution are single phase mixes of the liquid solvent and the refrigerant; a first absorber in which the lean solution absorbs a first partial flow of the refrigerant under a pressure drop; a second absorber in which the lean solution absorbs a second partial flow of the refrigerant directly thereafter while respectively dissipating heat; and an expeller in which the rich solution absorbs ambient heat and expels the refrigerant, a down tube arranged between an outlet for the lean solution from the first absorber and an inlet for the lean solution into the second absorber, wherein a hydrostatic pressure of a liquid column of the lean solution in the down tube compensates the pressure drop.

A sorption heat pump, comprising a gaseous refrigerant; a liquid solvent; a lean solution and a rich solution, wherein the lean solution and the rich solution are single phase mixes of the liquid solvent and the refrigerant; a first absorber in which the lean solution absorbs a first partial flow of the refrigerant under a pressure drop; a second absorber in which the lean solution absorbs a second partial flow of the refrigerant directly thereafter while respectively dissipating heat; and an expeller in which the rich solution absorbs ambient heat and expels the refrigerant, a down tube arranged between an outlet for the lean solution from the first absorber and an inlet for the lean solution into the second absorber, wherein a hydrostatic pressure of a liquid column of the lean solution in the down tube compensates the pressure drop.

A refrigeration system for cooling a refrigeration compartment. The refrigeration system comprises a cooling reservoir for cooling refrigerant in a first loop using energy recovered from an engine exhaust stream and a refrigeration circuit comprising a compressor drivable by an internal combustion motor, the compressor circulating refrigerant in a second loop. The refrigeration system comprises at least one heat exchanger in communication with the first and second loops to receive cooled refrigerant, and at least one blower for forcing air over the at least one heat exchanger. A controller selectively activates the internal combustion motor based on a temperature of the cooling reservoir.

A method for recovering heat (i.e., thermal) energy produced by computer hardware in blockchain (e.g., cryptocurrency) mining operations and utilizing that recovered heat energy in cooling modules. Also, a system for recovering heat energy produced by computer hardware in blockchain (e.g., cryptocurrency) mining operations and utilizing that recovered heat energy in absorption cooling modules which are an ammonia-water absorption refrigerator module and/or an absorption immersion cooling module.