A heat exchanger element has a heat-conducting body and a heat-transfer fluid pipe embedded in ducts having a channel-shaped locating section and two tabs connected flat to the heat-conducting body. To produce the heat exchanger element, foil strips are pressed into grooves so that they each form a section pressed into the grooves in a channel-like manner and laterally projecting tabs. A building panel has a heat exchanger element with a heat exchange surface, a cooling device and a collecting device, the cooling device being designed to cool the heat exchange surface in contact with the ambient air to a temperature below the dew point of the water vapour in the ambient air.

An exemplary embodiment of the present disclosure provides a flue gas outlet assembly including a flue gas inlet configured to connect to an exhaust outlet of a fuel burning device, a flue gas outlet, and a flue pipe condensate drain assembly including a condensate inlet, a condensate outlet, and a float valve disposed between the condensate inlet and the condensate outlet, the float valve including a bullet-shaped float, wherein the float valve is biased closed and is configured to open to permit a flow of condensate from the condensate inlet to the condensate outlet upon a sufficient amount of condensate collecting proximate the float valve.

Disclosed is a system for conditioning air, the system comprising: a heat exchanger comprising a plurality of heat transfer tubes extending between an accumulation header and an outlet header, an internal volume, and an external surface, wherein an air mover is disposed in fluid communication with an air mover in fluid communication with an air inlet and an air outlet, wherein the air mover is configured to urge a flow of air to be conditioned across the external surface of the heat exchanger, a reactor comprising an adsorbent material, a reactor inlet in fluid communication with the outlet header, and a reactor outlet, a vacuum pump comprising a vacuum pump inlet in fluid communication with the reactor outlet and a vacuum pump outlet in fluid communication with a system exhaust.

A hydronic floor heating system as it relates to an HVAC apparatus, approach and system. Aspects of the present system and approach may include a radiant floor optimization mode, low floor temperature in vacation mode, modifying a 300 Hz, or so, reading principle base on implementation of Pseudo-random jittering of a reading event improving short-term accuracy of the individual readings, and a combination of hardware and software filters for using thermal sensors with extended cable length.

A heating body, having multiple heat tubes filled with a working medium and run in parallel, and which have a first end and a second end, and having a heat source, which is thermally coupled to the first and/or second end of the heat tubes. To improve efficiency, reduce heating time, and achieve a homogeneous heat distribution, the first ends of the heat tubes are open and are fluidically connected to a first transverse connection tube and/or the second ends of the heat tubes are open and are fluidically connected to a second transverse connection tube, the heat tubes and the transverse connection tubes form a common cavity filled with the working medium, and the first or second transverse connection tube is thermally coupled to the heat source in order to absorb heat from the heat source.

A cooling module for solid-state refrigerant cooling includes an annular storing portion having a housing portion, low and high temperature side inflow paths, low and high temperature side outflow paths, first and second spaces between the first and second ends of housing flow paths and the low and high temperature side inflow paths, and first and second intermediate flow paths. The first intermediate flow path is in fluid communication with the low temperature side inflow path and the first space, and is configured to widen a flow of the heating medium flowing from the low temperature side inflow path to the first space. The second intermediate flow path is in fluid communication with the high temperature side inflow path and the second space, and is configured to widen a flow of the heating medium flowing from the high temperature side inflow path to the second space.

A novel solid-state heating element is disclosed. The heating element comprises a plurality of heating layers comprised of a mixture of carbon and a polymer or plastic. The heating layers are disposed on or infused into a substrate. Each heating layer can be disposed on, or infused into, its own substrate, or the heating layers can be disposed on or infused into opposites sides of the same substrate. A radiating element can be disposed in proximity to one or both of the heating layers. The radiating element absorbs the radiation put out by the heating layer(s) and reradiates heat. A heat transfer fluid such as air or a liquid can be directed across the radiating element and/or other areas of the heating element to transfer heat from the heating element to another location.

A flooring system has at least one girder, a first joist coupled to a first side of the girder, and a second joist coupled to a second side of the girder. The flooring system further comprises a joist tightening system that has a first end coupled to the first joist and a second end coupled to the second joist, the joist tightening system pulls the first joist and the second joist toward the girder thereby tightening the first joist and the second joist.

A cooking appliance according to an embodiment of the present invention comprises: a case having a cooking chamber formed therein; a door for opening/closing a front opening of the case; a steam generation device mounted on the exterior of the case; and a steam supply pipe for connecting the steam generation device and the cooking chamber, wherein the steam generation device can comprise: a housing fixed to the case; a drawer provided so as to be able to be withdrawn from and put into the housing, and into which water for generating steam is filled; and a heating unit mounted on the lower surface of the drawer so as to heat the water filled inside the drawer.

An apparatus can comprise a circuit and an electrical element coupled to the circuit. The circuit can include a pulse generator to generate an electrical pulse having a first power and a load. The electrical element can be configured to receive heat that is converted into electrical energy by the circuit to apply a second power, greater than the first power, to the load.