A fluid control system is provided that in one form includes a first flow channel, a second flow channel, a heater disposed in the second flow channel, and a fluid control device disposed upstream from the first and second flow channels. When the heater is turned on, the fluid control device changes a fluid flow rate through at least one of the first flow channel and the second flow channel. In another form, the fluid control system includes a bypass conduit, a heater disposed within the bypass conduit, and a fluid control device disposed near the inlet and outlet of the bypass conduit. In still another form, the fluid control system includes a regeneration device disposed downstream from at least one exhaust aftertreatment system and closes an outlet of the exhaust pipe.

A fluid control system is provided that in one form includes a first flow channel, a second flow channel, a heater disposed in the second flow channel, and a fluid control device disposed upstream from the first and second flow channels. When the heater is turned on, the fluid control device changes a fluid flow rate through at least one of the first flow channel and the second flow channel. In another form, the fluid control system includes a bypass conduit, a heater disposed within the bypass conduit, and a fluid control device disposed near the inlet and outlet of the bypass conduit. In still another form, the fluid control system includes a regeneration device disposed downstream from at least one exhaust aftertreatment system and closes an outlet of the exhaust pipe.

An electrical heating element for an electrical heating device is provided, wherein the electrical heating element is made from a coiled resistive wire with flat ribbon geometry and one or two connector assemblies, wherein the resistive wire with flat ribbon geometry is coiled into coils with an inner diameter, an outer diameter, and a distance between adjacent coils such that the flat side of the resistive wire with flat ribbon geometry runs parallel to the coil axis, and wherein the connector assemblies have at least one connection element that is in surface-area contact with a section of the resistive wire with flat ribbon geometry. In addition, an electrical heating device with such an electrical heating element and a method for manufacturing such an electrical heating device are also provided.

An electrical heating element for an electrical heating device is provided, wherein the electrical heating element is made from a coiled resistive wire with flat ribbon geometry and one or two connector assemblies, wherein the resistive wire with flat ribbon geometry is coiled into coils with an inner diameter, an outer diameter, and a distance between adjacent coils such that the flat side of the resistive wire with flat ribbon geometry runs parallel to the coil axis, and wherein the connector assemblies have at least one connection element that is in surface-area contact with a section of the resistive wire with flat ribbon geometry. In addition, an electrical heating device with such an electrical heating element and a method for manufacturing such an electrical heating device are also provided.

A fluid conditioning system having a housing within a fluid inlet and a fluid outlet. A rotating shaft extends within the housing and secures a conductive component exhibiting fluid flow redirecting vanes for communicating an inlet fluid flow with an outlet fluid flow. Magnets or electromagnets are arranged in a stationary array within the housing in proximity to the rotary conductive component and, upon rotating the conductive component relative to the magnetic plates, thermal conditioning of the fluid flow is generated from creation of high frequency oscillating magnetic fields and which is conducted through the rotating component for outputting through the outlet of the housing. Peltier or other thermoelectric generator elements can be incorporated into the housing. The conductive components or plates can include any of a number multi-metal/multi-alloy plate configurations.

A fluid conditioning system having a housing within a fluid inlet and a fluid outlet. A rotating shaft extends within the housing and secures a conductive component exhibiting fluid flow redirecting vanes for communicating an inlet fluid flow with an outlet fluid flow. Magnets or electromagnets are arranged in a stationary array within the housing in proximity to the rotary conductive component and, upon rotating the conductive component relative to the magnetic plates, thermal conditioning of the fluid flow is generated from creation of high frequency oscillating magnetic fields and which is conducted through the rotating component for outputting through the outlet of the housing. Peltier or other thermoelectric generator elements can be incorporated into the housing. The conductive components or plates can include any of a number multi-metal/multi-alloy plate configurations.

A heater unit includes a first terminal; and a resistance heating type heater electrically connected to the first terminal.

A heater unit includes a first terminal; and a resistance heating type heater electrically connected to the first terminal.

The present invention relates to a vehicle radiation heater being configured to perform heating by directly emitting radiant heat toward a passenger at an early stage of starting of a vehicle in winter. The vehicle radiation heater according to the present invention can be simple in structure, thereby being easy to manufacture, can quickly emit high-temperature radiant heat over the entire area of the heater, thereby enhancing rapid and comforting heating effects, and can maintain a constant temperature, thereby preventing a risk of overheating.

The present invention relates to a vehicle radiation heater being configured to perform heating by directly emitting radiant heat toward a passenger at an early stage of starting of a vehicle in winter. The vehicle radiation heater according to the present invention can be simple in structure, thereby being easy to manufacture, can quickly emit high-temperature radiant heat over the entire area of the heater, thereby enhancing rapid and comforting heating effects, and can maintain a constant temperature, thereby preventing a risk of overheating.