An auxiliary heater with a casing enclosing internal components which components include a heat exchanger separate from and outside the coolant tank and wherein two coolant loops each have their own coolant pumps and wherein a potable water loop exchanges heat with coolant within the heat exchanger. A control circuit provides enhanced coolant flow through the heat exchanger when the call for hot water is significant without significantly reducing the temperature of the hot water being used. A level switch within the coolant tank prevents coolant pumps from running without pump coolant and a filling and air purging operation improves the initial filling operation of the auxiliary heater with coolant and also prevents the coolant pump from running dry. A user switch may dedicate the hot coolant from the coolant tank to either the production of hot potable water or it may share both hot water and space heating.

The present disclosure provides a dual cooling water heater including a main body on which a substrate is seated, a flow path forming part connected to the main body and having first and second flow paths provided on one surface thereof, a first heating element disposed on the other surface of the flow path forming part and configured to heat the first flow path, a second heating element disposed on the other surface of the flow path forming part and configured to heat the second flow path, and a control unit configured to control a temperature and a flow rate of cooling water moving through the first flow path and a temperature and a flow rate of cooling water moving through the second flow path by controlling a temperature of the first heating element and a temperature of the second heating element.

The heater module includes a fluid pump including a pump inlet configured to introduce cooling water thereinto, a pump outlet configured to pressurize and discharge the introduced cooling water, cooling water heating heater including a heater inlet configured to introduce thereinto the cooling water discharged from the pump outlet of the fluid pump, a heating unit configured to heat the introduced cooling water, a heater outlet configured to discharge the heated cooling water, a flow channel switch valve for switching a circulation flow channel of the cooling water, wherein the fluid pump is integrally formed with one side of the cooling water heating heater to embody both a heating mode and a battery temperature-rising mode by one heater module for heating cooling water. Thus, a connection hose for connection components is removed or a length thereof is minimized, a fluid pump and a valve housing are reduced, thereby reducing costs.

An electric heater device includes: a plurality of pipes stacked with each other through a predetermined clearance as a pipe stacked body, a fluid flowing inside the plurality of pipes; a heating element disposed in the clearance between the plurality of pipes; a housing that houses the plurality of pipes and the heating element, the housing being formed separately from the pipe stacked body; and a thermal resistance structure that increases a thermal resistance between the pipe stacked body and the housing.

An electric heating device has several PTC heating elements that are arranged in a circulation chamber. The electric heating device includes a heating element casing which fits as a structural unit at least one PTC element and contact plates that energize said PTC element and form contact strips for an electrical plug connection. A partition wall separates the circulation chamber from a connection chamber in which the contact strips of the PTC heating element penetrating the partition wall are exposed and are electrically connected. A plug connection is formed between the partition wall and the PTC heating element and via which the PTC heating element is held in a frictionally engaged and/or in positive fit manner on the partition wall in the direction of insertion.

The present invention relates to a coolant heater. The objective of the present invention is to provide a coolant heater, wherein an assembly formed by stacking sheet-type heaters is integrated with a housing in which coolant circulates, so as to minimize heat loss and thus maximize heating efficiency and achieve free capacity diversification through a sheet-stacking shape.

Disclosed is a vehicle-mounted gas water heater, wherein the water flow pipe comprises a water inflow section, a first heating section, a second heating section and a water outflow section, wherein the water inflow section is shortened, wherein the water inflow section is shortened, a heating section is rapidly heated directly by the combustion heating device, and the second heating section is heated by winding on the heat exchanger, so that, formation of condensed water at the water inflow section is reduced due to reduction of surface area, condensed water formed on the surface of the first heating section is rapidly evaporated, and it is difficult for condensed water to form on the surfaces of the second heating section and the outflow section.

Vehicle air conditioning apparatus comprising air conditioning case with inlet and outlet, partition wall dividing the inner space into a first and a second space portions; cooling heat exchanger disposed inside the air conditioning case to span the first and second space portions and connected to the outlet; and heat exchanger disposed inside the air conditioning case to span the first and second space portions. The air conditioning case includes a first flow path disposed in the second space portion below the heat exchanger; a channel part disposed behind the heat exchanger, with its entrance communicating with the first flow path, and exit communicating with the first space portion. Accordingly, a portion of air flowing to the first flow path via cooling heat exchanger without passing through heat exchanger is guided to the first space portion via the channel part without being mixed with air passing through heating heat exchanger.

A heating device is provided with plates stacked one on top of another. At least one first fluid channel is formed in a fluid-tight manner between a first plate package with a first and a second plate. An electrical heating element is arranged between a first plate of the first plate package and an additional plate. The electrical heating element is accommodated between the two plates in a sealed manner and is electrically insulated, wherein an inlet-side and an outlet side fluid connection of the first fluid channel is arranged on the second plate of the first plate package. The electrical heating element has a connection device for electrical contacting, which is connected to the electrical heating element and protrudes through a window in the second plate of the first plate package, wherein the fluid connections and the window are arranged adjacent to opposing lateral edges of the second plate.

A heating medium heating device includes: a plate-shaped PTC heater formed by making compressive heat transfer sheets cover individually two surfaces of a PTC element; a first heating medium distribution box including a first matching surface in which a PTC heater accommodating recess is formed, the PTC heater accommodating recess including a bottom surface with which the compressive heat transfer sheet located on a first-surface side of the PTC heater is in close contact; a second heating medium distribution box including a flat second matching surface that closes the PTC heater accommodating recess by being bonded, liquid-tightly via a liquid gasket, to the first matching surface, the second matching surface being a surface with which the compressive heat transfer sheet located on a second-surface side of the PTC heater is in close contact; and a barrier part rising from a peripheral edge part of the PTC heater towards the second matching surface.