A method and device are provided for purifying and recycling water vapor from a coal drying process. Included are a temperature-lowering and dehumidifying process, a flash distillation stripping process, and a vacuum condensing process. A condensing tower receives a temperature-lowered exhaust gas with high humidity from a cooling tube and a condensed water of 5˜60° C. from a flash distillation tank, allowing the exhaust gas and the condensed water to contact each other in a vapor-liquid reverse manner, to lower the temperature and dehumidify the exhaust gas. The flash distillation tank performs a vacuum flash distillation to the condensing water pumped therein from the condensing tower. Water vapor of 5˜60° C. evaporated through flash distillation in the flash distillation tank enters into the demisting washer to be dehumidified and then is condensed. The condensed water in the vapor condenser is transferred into a recycled water tank. Non-condensable gas is discharged out.

The present disclosure relates to a seawater desalination system which improves energy efficiency by applying a heated cooling water discharged from a nuclear power plant and high-temperature steam generated in a nuclear reactor to seawater desalination. A seawater desalination system related to an exemplary embodiment of the present disclosure includes: a steam supply pipe 40 which supplies heat exchange steam that is a part of the steam discharged from a turbine 20; a seawater supply pipe 36 which diverges from a discharge pipe 34; and a heat exchanger 50 which is connected to the steam supply pipe 40 so as to be supplied with the heat exchange steam, and connected to the seawater supply pipe 36 so as to be supplied with first seawater that is a part of the seawater discharged from a condenser 30, in which the heat exchanger 50 increases a water temperature of the first seawater by using heat included in the heat exchange steam, and the first seawater with the increased water temperature is supplied to the fresh water-generating unit 2 through a connection pipe 4, such that desalination of the first seawater is performed.

The Cover Handler System is mechanical mechanism that completes the task of removing large covers from industrial sized boilers, heat exchanges and condensers even in conditions cramped by walls, pipes and other boilers. The mechanism typically attaches to the top of the boiler from which will extend a swing assembly, from which horizontally extends an I-beam, along which slides a roller assembly, from which descends vertically a hanger which provides means for a bronze bushing supported cover assembly. The cover is removed and rotated out of the way by the cover handler's three means of articulation by the rotating swing assembly, the sliding roller assembly and rotating cover mounts. The cover removal system ceases to be arduous and time consuming. The complex operation of removing and replacing the cover is accomplished safely in a short amount of time even in the most cramped conditions.

An atmospheric water generation system (20) comprising a casing (22); a water condensing heat exchanger (62) located in the casing to receive ambient air from an air inlet (42); a chiller unit (80) located in the casing to provide the water condensing heat exchanger (62) with a chilled coolant; and an electronic control system (500) configured to: monitor one or more characteristic parameters of the ambient air outside and nearby the casing (22), and start the water generation on the basis of the monitored value (AT, AH, AP) of said one or more air characteristic parameters.

A device for the thermal treatment of material comprises a housing having a heatable housing jacket, which surrounds a treatment chamber and forms a rotationally symmetrical treatment surface extending in an axial direction, and a drivable rotor, which is arranged in the treatment chamber and extends coaxially. The rotor comprises a shaft, arranged in a manner distributed over the circumference of which are spreading elements. The device also comprises a condensation space, in which a condenser is formed and into which gaseous material components escaping from the material during the thermal treatment can pass, a condensate outlet for discharging the material components condensed in the condensation space, and a vacuum connection, which is fluidically connected to the condensation space. The vacuum connection is arranged in a region of the housing that lies downstream of the treatment surface, as viewed in the transport direction of the material.

A multimode system for cooling and desalination includes a humidification-dehumidification (HDH) system, an ejector cooling cycle (ECC) system and valves. The HDH system includes a heater, a humidifier and a dehumidifier. The ECC system includes a generator, an evaporator, an ejector and a condenser. The valves are configured to connect to inlets and outlets of the heater, the generator and a heat source so that by selectively opening and closing the valves, the heat source is connected to the heater while disconnected from the generator, or connected to the generator while disconnected from the heater, or connected to both the heater and the generator, or disconnected from both the heater and the generator. The ECC system and the HDH system are connected at the condenser for heat exchange.

This disclosure is directed to a system for generating liquid water from a gaseous ambient environment containing water vapor. The system includes a mobile trailer and a liquid water generator provided on the mobile trailer. The liquid water generator is configured to generate liquid water by condensing the water vapor from the gaseous ambient environment. An energy source provided on the mobile trailer that is self-contained and is configured to collect and store energy sufficient to power the liquid water generator.

A multimode system for cooling and desalination includes a humidification-dehumidification (HDH) system, an ejector cooling cycle (ECC) system and valves. The HDH system includes a heater, a humidifier and a dehumidifier. The ECC system includes a generator, an evaporator, an ejector and a condenser. The valves are configured to connect to inlets and outlets of the heater, the generator and a heat source so that by selectively opening and closing the valves, the heat source is connected to the heater while disconnected from the generator, or connected to the generator while disconnected from the heater, or connected to both the heater and the generator, or disconnected from both the heater and the generator. The ECC system and the HDH system are connected at the condenser for heat exchange.

The invention provides a clog-free condensation system for a pyrolysis apparatus used in the thermal degradation of waste plastics that contain polyethylene terephthalate (PET). A conduit carries vapor from a pyrolysis reactor to a condenser having an inlet for an oil-immiscible solvent stream; a liquid outlet for removal of the oil-immiscible solvent, benzoic acid, and other condensed pyrolysates; and a vapor outlet to pass uncondensed vapors. A liquid-liquid phase separator connected to the liquid outlet continuously separates the two immiscible phases. Benzoic acid is precipitated and removed from the oil-immiscible phase, and the oil-immiscible solvent is returned to the condenser as a solvent stream. The invention provides a method for condensing PET pyrolysis vapors without formation of clogs in the condensation apparatus, and provides a method for the continuous recovery of benzoic acid and other condensable pyrolysates from a PET-containing waste plastic stream.

A device for the thermal treatment of material comprises a housing having a heatable housing jacket, which surrounds a treatment chamber and forms a rotationally symmetrical treatment surface extending in an axial direction, and a drivable rotor, which is arranged in the treatment chamber and extends coaxially. The rotor comprises a shaft, arranged in a manner distributed over the circumference of which are spreading elements. The device also comprises a condensation space, in which a condenser is formed and into which gaseous material components escaping from the material during the thermal treatment can pass, a condensate outlet for discharging the material components condensed in the condensation space, and a vacuum connection, which is fluidically connected to the condensation space. The vacuum connection is arranged in a region of the housing that lies downstream of the treatment surface, as viewed in the transport direction of the material.