A system for recovering water from air includes a skirt supported by legs and at least one interior wall suspended from the skirt. At least one exterior wall extends from an accumulator and is spaced apart from and substantially parallel to the at least one interior wall, thereby defining a flow channel between the at least one interior wall and the at least one exterior wall. At least one thermoelectric cooler (TEC) is connectable to an electrical power source for transferring heat from a cool side of the TEC to a warm side of the TEC, the cool side being positioned on the at least one interior wall, not in the flow channel, for cooling the at least one interior wall, the at least one interior wall defining a condensing surface proximate the at least one TEC.

A compartment comprising at least one target area susceptible to condensed water formation includes at least one condensed water collector is presented. The condensed water collector comprises at least a first portion arranged to collect condensed water from the at least one target area and at least a second portion outside of the at least one target area. A porous material is arranged between the first portion and the second portion. The condensed water collector is configured to transport the collected condensed water. The compartment further including a condensed water remover configured to remove condensed water from the second portion thereby facilitating transportation of condensed water from the first portion to the second portion via the porous material.

A system for condensing moisture in a moist gas stream entering or leaving a bioreactor includes a condenser container, the condenser container comprising: an outer wall surface and an inner wall surface, the inner wall surface defining an interior chamber for holding a fluid; and a first fitment attached to the outer wall surface and forming a first port configured to allow the moist gas stream to flow into the interior chamber; a second fitment attached to the outer wall surface and forming a second port configured to allow a dried gas to flow from the interior chamber and out of the second port; and a cooling device in contact with at least one portion of the outer wall surface and arranged to cool the at least one portion of the outer wall surface.

An acid purifier, comprising: a container (1) for an acid to be purified; a heater (2); a condenser (3) including a Peltier semiconductor cooler, a condenser body (600) and a refrigerant temperature sensor; a purified acid liquid collection bottle (4) connected with the condenser; a controller; an integrated liquid level control component (300) for the acid to be purified, connected with the container (1) for the acid to be purified, and arranged in such a way that a liquid level pipe (320), a liquid adding funnel (310) and a waste liquid discharge valve (330) are integrated; and an acid liquid temperature sensor (400, 500) arranged in the acid to be purified.

Systems and processes capable of cooling gases, liquids, and solids without requiring the use of conventional refrigerants. Such a system or process for cooling a process fluid involves a passive cooling device that receives the process fluid from a reservoir and cools the process fluid by thermal conduction to a heat sink, an active cooling device that receives the process fluid from the passive cooling device and cools the process fluid with a coolant cooled by at least one thermoelectric device, and a housing that encloses the passive and active cooling devices and serves as the heat sink for the passive cooling device.

A method for separating components from a fluid is disclosed. A cooling element is provided and is disposed in contact with a distal side of one or more thermally-conductive surfaces. One or more resistive heating elements are provided and are disposed in contact with or embedded in a proximal side of the one or more thermally-conductive surfaces. A fluid comprising one or more secondary components is provided. The fluid is passed across the one or more thermally conductive surfaces, the one or more secondary components freezing, crystallizing, desublimating, depositing, condensing, or combinations thereof, out of the fluid. The one or more resistive heating elements engage such that the one or more solid secondary components detach and pass out the solids outlet. The one or more resistive heating elements disengage, restarting production of the one or more solid secondary components.

A uniform external field can enhance condensation on a superhydrophobic surface. Jumping droplets on superhydrophobic surfaces accumulate a positive charge which promises the manipulation and control of jumping behavior using external electric fields.

An electric motor-operated food processor has a base unit having an electric motor and a preparation vessel that can be arranged on the base unit. A heater and agitator are allocated to the preparation vessel. The food processor can have a distillation apparatus that can be connected with the preparation vessel. The distillation apparatus has a steam receptacle, a condenser and a liquid dispenser. The preparation vessel and steam receptacle are connected in terms of flow when the preparation vessel and distillation apparatus are in a connected state.

The present disclosure describes an apparatus that may be used to generate desalinated water from a supply of untreated water using a photovoltaic cell. The front surface of the photovoltaic cell is partially enclosed to form an evaporation chamber. The front surface of the photovoltaic cell is exposed to sunlight or another light source. This exposure results in power generation by the photovoltaic cell and also heats the air in the evaporation chamber. Untreated water is subsequently introduced into the evaporation chamber. Upon contacting the heated air and the front surface of the photovoltaic cell, a portion of the untreated water evaporates to generate water vapor. The water vapor is then removed from the evaporation chamber and transported to a condensation chamber. The water vapor is cooled in the condensation chamber to yield desalinated water.

A compartment comprising at least one target area susceptible to condensed water formation includes at least one condensed water collector is presented. The condensed water collector comprises at least a first portion arranged to collect condensed water from the at least one target area and at least a second portion outside of the at least one target area. A porous material is arranged between the first portion and the second portion. The condensed water collector is configured to transport the collected condensed water. The compartment further including a condensed water remover configured to remove condensed water from the second portion thereby facilitating transportation of condensed water from the first portion to the second portion via the porous material.