A steam heating apparatus, including a housing, a heater, a water inlet, and a steam outlet. The heater includes a base and a heating body vertically extending down from the base. The heating body includes a water inlet channel, a steam outlet channel, and heating pipes. The water inlet channel and the steam outlet channel are located between a pair of vertical heating pipes among the heating pipes. One end of the water inlet channel is communicated with the water inlet provided at one end of the heater, and the other end of the water inlet channel is opened to allow steam to flow out. The steam heating apparatus can fully utilize the heat of the heater, and the steam conversion efficiency and quality are higher. Meanwhile, the problem of blocking is prevented, and the performance of the heating apparatus is improved.

The invention relates to a device (1) for generating steam. The device (1) comprises a water outlet arrangement (2) having an open end (3) to spray water onto a water receiving arrangement (4). The water receiving arrangement (4) comprises an interior surface (5) defining a chamber (6) in which the open end (3) is arranged so that water sprayed from the open end (3) is sprayed onto the interior surface (5). The device further comprises a heating element (7) for heating the interior surface (5) up to a temperature for generating steam from water sprayed on the interior surface (5). The interior surface (5) is formed by two separate cavities (14a, 14b), the open end (3) comprising a spray nozzle (2) received within each cavity (14a, 14b) so that each spray nozzle (2) sprays water onto a region of the interior surface (5), each region being defined by the cavity (14a,14b) in which a respective spray nozzle (2) is received. This allows the water sprayed by the water outlet arrangement (4) be more uniformly spread on the interior surface (5), leading to more effective heating and more steam may be generated per unit time.

A small-sized fluid heating/cooling apparatus for heating or cooling a large amount of gas or liquid at a low cost. Structures where a flow passage for a fluid is formed in a heated or cooled base formed in a plate shape or a column shape, and a fluid which has passed through the narrowed flow passage impinges on a wall of a side face of the base vertically to perform heat exchange are connected in series. Heat exchange is instantaneously performed in a small space and manufacture of a mechanism performing such an operation is easy. A material constituting the flow passage may be a metal or ceramics, and a small-sized fluid heat exchanging apparatus can be manufactured at a low cost.

Provided are a steam spraying apparatus and a clothing drying machine including the same. The steam spraying apparatus include a flow passage forming unit, a steam generating heater, and a nozzle. The flow passage forming unit has a flow passage for guiding water introduced through an inlet to an outlet. The steam generating heater applies heat to water flowing along the flow passage. A nozzle sprays steam generated by the heating of the steam generating heater at a certain pressure.

A steam generator includes a generator body including an inlet through which fluid is introduced and or outlet through which the fluid is discharged, a first flow channel providing a flowing path for the fluid is introduced into the generator body through the inlet, a second flow channel to guide the fluid from the first flow path to the outlet, and a heater to heat the generator body, the heat of the generator body being exchanged with the fluid guided through the first and second flow channels, and greater amount of heat being provided at the first flow channel than the second flow channel.

A steam power generating system is provided with an inflow pipe, a split-flow member disposed rearward of a screw-plug with the inflow pipe passing through, a blocking member disposed rearward of the split-flow member, a cylindrical case disposed rearward of the blocking member, a thermal conductor in the case, a base disposed rearward of the case, a porous member disposed rearward of the base, a hollow cylinder secured onto the screw-plug, the split-flow member, the blocking member, the cylindrical case, and the porous member, a heat source around the cylinder, an insulation member around the heat source, a steam output disposed rearward of the porous member, a power conversion device disposed rearward of the steam output for receiving steam therefrom, and a cooling device interconnecting the power conversion device and a pump.

A generator of ultrapure steam and a corresponding steam generating method uses a heated, fritted refractory glass plate as a water-to-steam interface dividing a first chamber, with water on one side of the plate and steam on the other. Water is continuously injected into interstices of the plate, held fixed in the chamber, where the water evaporates and migrates upwardly to where a steam cloud is formed that exits the chamber and into a second chamber that is a saturation housing where an air stream removes steam from the exit, preventing steam condensation, and delivering a steam jet out of the housing through a port.

A vaporizer apparatus includes a liquid inlet; a plurality of plates in a stacked arrangement and configured with openings and surfaces defining a tortuous path for a liquid through the plurality of plates; an atomizer configured to atomize liquid from the liquid inlet and inject a spray of the liquid toward a first plate of the plurality of plates, wherein the plurality of plates is configured to direct a flow of the liquid through the tortuous path from a first end corresponding to the first plate and output a vapor of the liquid at a second end of the tortuous path corresponding to a last plate of the plurality of plates; and at least one heating element configured to heat the plurality of plates to vaporize the liquid along its flow through the tortuous path and generate the vapor.