A heat exchange cell is described comprising a containment casing comprising a rear wall, a front wall and a peripheral side wall, a helically-shaped heat exchanger comprising at least one tubular duct for the flow of a first heat transfer fluid coiled about a longitudinal axis of the helix according to a plurality of coils and mounted in the containment casing; a feeding zone of a second heat transfer fluid, intended for the heat exchange with the first heat transfer fluid, defined in the casing coaxially and internally with respect to the heat exchanger; a first chamber for collecting the second heat transfer fluid externally defined with respect to the heat exchanger between a radially outer wall thereof and the peripheral side wall of the containment casing; and a second chamber for collecting the second heat transfer fluid at least partially delimited by at least one separating element.

The combustion chamber subassembly comprises a top bell member defining an interior combustion chamber and an exterior, the top bell member including a top diffuser wall, a first side wall extending from the top diffuser wall toward the interior combustion chamber of the top bell member, a second side wall extending from the first side wall toward the exterior of the top bell member, and a gasket that is attached to the top bell member, contacting the first side wall and the second sidewall.

A heat exchange cell (10) is described comprising a helically-shaped heat exchanger (13), mounted in a containment casing (11), in which a first heat transfer fluid circulates; a first heat exchange chamber (22), defined in the casing (11), in which a first heat exchange portion of the heat exchanger (13) is housed and in which a first collection chamber (15) of the second heat transfer fluid is defined externally to the heat exchanger (13); a second heat exchange chamber (26) defined in the casing (11), in which a second heat exchange portion of the heat exchanger (13) is housed and in whichexternally to the heat exchanger (13)a second collection chamber (16) of the second heat transfer fluid is defined; and a fluid outlet passage (35) from the second heat exchange chamber (26) defined in a peripheral side wall (11c) of the containment casing (11) in proximity to a rear wall (11d) thereof. The first and second heat exchange chambers (22; 26) are separated internally to the heat exchanger (13) by a first separating element (14) comprising a substantially plate-shaped body and externally to the heat exchanger (13) by at least a second separating element (32) extending radially between a radially outer wall (13a) of the heat exchanger (13) and the peripheral side wall (11c) of the containment casing (11) so as to define at least one passage (17) of fluid between the first (15) and the second (16) collection chamber of the second heat transfer fluid. The heat exchange cell (10) further comprises a pair of axial separator baffles (24a; 24b), axially extending between the second separating element (32) and the rear wall (11d) of the containment casing (11), and configured to separate a first portion (16a) of the second collection chamber (16) of the second heat transfer fluid defined upstream of the axial separator baffles (24a; 24b) from a second portion (16b) of the second collection chamber (16) of the second heat transfer fluid defined downstream of the baffles (24a; 24b).

The present disclosure relates generally to protective devices and cover members. In some embodiments, cover members are provided that are operable to protect covered components and to allow heat dissipation from the components. Cover members of the present disclosure are suitable for use with heat exchangers including, for example, those provided with hot water pressure washers.

A liquid heating apparatus includes a top portion with a burner unit, a coil, an external housing, and an internal housing. The burner unit is arranged to burn a fuel so as to generate a downward directed flame. The coil includes first and second layers of windings. The internal housing is arranged within the external housing. The apparatus is in a substantially upright position during operation. A compartment between the internal housing and the external serves as a first liquid reservoir. The flame from the burner unit is peripherally contained by an inner part of the first layer of windings of the coil. The first layer of windings is configured to direct the flame or exhaust gases downwards. The flame or exhaust gases are redirected such that the they contact all of the second layer of windings, the internal housing inner wall, and the first layer of windings

In a temperature control apparatus for controlling the temperature of a load by supplying high-temperature circulating liquid to the load, a device in which a helical channel portion of a first heat exchange channel through which circulating liquid flows is housed in a second heat exchange channel formed of a channel space in a hollow shell through which coolant flows is used as a heat exchanger for cooling the circulating liquid, cylindrical members are individually fitted on an inflow channel portion and an outflow channel portion connected to opposite ends of the helical channel portion of the first heat exchange channel, and the cylindrical members are each fixed to the shell of the heat exchanger with a weld.

An induction heater for a vehicle according to the present invention heats a coolant of the vehicle using an induction heating method, and more particularly, is easy to mold and has a reduced heating density by applying a plate-shaped coil and plate-shaped heating elements.

An induction heater for a vehicle according to the present invention heats a coolant of the vehicle using an induction heating method, and more particularly, is easy to mold and has a reduced heating density by applying a plate-shaped coil and plate-shaped heating elements.

A heating device apparatus is provided, which includes: a first cavity, a heating member, a second cavity, a heat conducting member, a temperature detector and a controller. The heating member heats the fluid in the first cavity. The fluid inlet of the second cavity is in communication with the fluid outlet of the first cavity. The heat conducting member isolates the first cavity from the second cavity. The temperature detector detects the temperature of the fluid in the second cavity. The controller controls the heating of the heating member according to the temperature detected by the temperature detector. The fluid flows into the first cavity, is heated by the heating member, then flows into the second cavity, and performs heat exchange with the fluid in the first cavity through the heat conducting member when the fluid flows through the second cavity.

A heating device apparatus is provided, which includes: a first cavity, a heating member, a second cavity, a heat conducting member, a temperature detector and a controller. The heating member heats the fluid in the first cavity. The fluid inlet of the second cavity is in communication with the fluid outlet of the first cavity. The heat conducting member isolates the first cavity from the second cavity. The temperature detector detects the temperature of the fluid in the second cavity. The controller controls the heating of the heating member according to the temperature detected by the temperature detector. The fluid flows into the first cavity, is heated by the heating member, then flows into the second cavity, and performs heat exchange with the fluid in the first cavity through the heat conducting member when the fluid flows through the second cavity.