Abstract: A fuel cell system and a control method thereof are capable of preventing anode flooding due to a temperature difference between a stack and reformate upon starting a fuel cell system. The method of controlling a fuel cell system including steps of detecting a temperature of a fuel cell stack, detecting a temperature of reformate that is generated in a fuel reformer and then is supplied to the fuel cell stack through a heat exchanger, and setting the temperature of the reformate to be lower than the temperature of the fuel cell stack during a starting time of the fuel cell system.

Abstract: A fuel cell system that effectively processes a flue gas generated from a heat source of a fuel reforming apparatus. The fuel reforming apparatus generates a reforming gas containing hydrogen through a reformation reaction of the fuel from a fuel supply, and a fuel cell main body generates electrical energy through an electrochemical reaction of the reforming gas with an oxidizing agent. The fuel reforming apparatus includes a reforming reaction part and a heat source. The reforming reaction part induces a reforming reaction in the fuel, and the heat source provides heat energy to the reforming reaction part. A flue gas postprocessor induces an oxidation-reduction reaction in a flue gas exhausted by a combustion reaction of the heat source to decrease toxic ingredients, such as CO, hydrocarbons, and NOx, in the flue gas.

Abstract: A catalyst for a reformer of a fuel cell including an active component and a carrier supporting the active component and including zinc oxide. The active component includes a transition metal and a platinum-group metal. Here, the catalyst has a relatively high reforming efficiency with a relatively low amount of platinum-group metal and a reaction temperature that is less than 500° C. to ensure reactor durability.

Abstract: A fuel reforming apparatus includes an oxidation reaction unit in which an oxidation catalyst is formed, a reforming reaction unit in which a reforming catalyst is formed, and an ignition unit for igniting a hydrocarbon-containing fuel and an oxidant and preheating the oxidation catalyst in an early driving stage. The oxidation reaction unit has a first section and a second section respectively formed opposite to each other with the oxidation catalyst interposed therebetween and forms a stream of the fuel and the oxidant flowing to the second section through the oxidation catalyst from the first section, the ignition unit being located in the second section.

Abstract: A plate-type reactor for a fuel cell is provided. The plate-type reactor includes a plate-type reactor main body having a path for allowing a reactant to flow and a catalyst formed in the path to promote a chemical reaction of the reactant. The catalyst is composed of a first catalyst layer coated on a surface of the path and a second catalyst layer filled in a remaining space of the path.

Abstract: A desulfurizing device for a fuel cell includes a dehydrating element for absorbing moisture in a hydrocarbon fuel, and a desulfurizing element for absorbing a sulfur compound included in the hydrocarbon fuel that flows out of the dehydrating element. In another embodiment, the desulfurizing device for a fuel cell includes a dehydrating element for absorbing moisture included in a fuel, and a desulfurizing element. The desulfurizing element absorbs a sulfur compound included in the fuel flowing out of the dehydrating element if temperature of the desulfurizing element is below a predetermined temperature, and the desulfurizing element desorbs a sulfur compound included in the desulfurizing element whenever the desulfurizing element is heated above the predetermined temperature.

Abstract: A carbon monoxide treatment apparatus according to an exemplary embodiment of the present invention includes: a reactor body; a partitioning plate located inside the reactor body for partitioning an internal space of the reactor body into a first section and a second section; a channel member in the first section for transporting an introduced gas including a reformed gas and an oxidant gas to the second section; and a reaction unit around the channel member of the first section for reducing a concentration level of carbon monoxide in the introduced gas moving through the first section by utilizing a preferential oxidation reaction of the carbon monoxide and the oxidant gas of the introduced gas, wherein moisture of the introduced gas that has been partially condensed when passing through the channel member is stored in the second section.

Abstract: Provided is a reaction vessel for a fuel cell, and more particularly to a reaction vessel exhibiting improved thermal efficiency, and a reaction device for a steam reforming reaction for a fuel cell. The reaction device includes a cylindrical reaction catalyst chamber on which a target reaction catalyst for a predetermined target reaction is disposed; and a tubular oxidation catalyst chamber surrounding the reaction catalyst chamber, comprising an oxidation reaction catalyst therein. The reaction device according features an increased contact area between catalyst and gas, and rapidly heating of the gas in contact with the catalyst to a desired reaction temperature.

Abstract: A reformer for a fuel cell system includes a heating source for generating heat by a reaction of a fuel and an oxidant using an oxidizing catalyst, and a reforming reaction part for generating hydrogen by a reforming catalyst reaction. The oxidizing catalyst includes a solid acid, including a strong acid ion and an inorganic oxide, and a platinum-based metal. The reformer for a fuel cell system can start a fuel oxidation catalyst reaction at a low temperature with the heating source having a simplified structure.

Abstract: A method of driving a heating unit for a fuel cell reformer, a reformer applied with the method for driving the heating unit, and/or a fuel cell system including the reformer. The method includes: supplying an oxidant to the heating unit and absorbing the oxidant by a fuel oxidizing catalyst of the heating unit; supplying a fuel at an excessive amount to the heating unit and absorbing the fuel by the fuel oxidizing catalyst of the heating unit; and supplying the fuel and the oxidant to the heating unit at a stoichiometric ratio of the fuel to the oxidant ranging from 1:1 to 2:1, wherein the heating unit generates heat through an oxidizing catalyst reaction between the fuel and the oxidant.

Abstract: A fuel oxidizing catalyst, a method of preparing the same, and a reformer and a fuel cell system including the same. In one embodiment, the fuel oxidizing catalyst for a fuel cell includes CeO2, MO (wherein M is a transition metal), and CuO. In this embodiment, the fuel oxidizing catalyst has a relatively high (or excellent) catalytic activity for a fuel oxidizing catalyst reaction and performs a fuel oxidizing catalyst reaction at a relatively low temperature even though it does not include a noble metal.

Abstract: The present invention relates to a reaction vessel for fuel cells, and more particular to a reaction vessel capable of obtaining reaction temperature promptly at the time of initial operation and a reaction device to form a reforming device of the fuel cell using the same. The reaction device of the present invention includes a reaction vessel that includes a monolithic chain. The monolithic chain has a first wall, a second wall, and a layer of pleats interposed between the first wall and the second wall. A plurality of openings are formed on each of the top side and the bottom side of the monolithic chain. One of the first wall and the second wall being made of an insulating material. The layer of pleats is made of a conductive material, and electric power is applied to generate heat at initial reaction operation. Once the reaction is activated, the reaction vessel produces heat through an oxidation reaction.

Abstract: A fuel reformer using radiation comprises: a reforming reactor including a reforming catalyst for shifting fuel into a desired substance; a heater for supplying heat to the reforming catalyst; and a transparent inner wall positioned between the reforming reactor and the heater. With the present invention, the heat energy of the heater is transferred to the reforming catalyst in a radiation form so that the thermal efficiency of the fuel reformer can be improved.

Abstract: A reformer of a fuel cell system is disclosed. One embodiment of the reformer includes a reforming reactor generating reformed gas containing hydrogen by reforming hydrogen-containing fuel; and a CO remover removing carbon monoxide contained in the reformed gas generated from the reforming reactor, wherein the CO remover is disposed to be inclined in a predetermined angle to a moving path of the reformed gas exhausted from the reforming reactor and connected to the reforming reactor so as to communicate fluid therebetween, whereby the CO remover is not subject to the heat energy effect by a heat transfer effect due to air convection from the reforming reactor, making it possible to keep the CO remover an optimal state to improve reforming efficiency.

Abstract: A PROX reactor integrated with a heat exchanger and an operating method thereof capable of effectively controlling temperature of a preferential oxidation reactor so as to obtain optimal activation and yield. The PROX reactor integrated with a heat exchanger of the present invention includes a pipe having an inlet and an outlet, a heat exchanger cooling gas passing through the pipe, a catalyst part positioned at the rear end of the heat exchanger, upon considering the flow of gas, and shifting carbon monoxide contained in the gas into other substances; and a temperature sensor measuring the temperature of the gas coming out through the catalyst part.

Abstract: Disclosed are a carbon monoxide remover and a fuel cell reformer including the same. In the reformer, a reformed gas produced from a reforming reaction unit when the reformer is initially driven is used as a fuel for a heat source unit supplying heat to a water gas shift reaction unit. The carbon monoxide remover is connected to the reforming reaction unit that changes fuel into reformed gas with hydrogen. The carbon monoxide remover lowers carbon monoxide contained in the reformed gas. The carbon monoxide remover includes a heat source unit employing the reformed gas as a fuel; and a water gas shift reaction unit provided with a shift catalyst using heat from the heat source unit. The shift catalyst lowers the concentration of carbon monoxide in the reformed gas through reaction between water and carbon monoxide.

Abstract: Disclosed is a fuel cell system which includes a generator, a reformer generating a reformed gas by reforming a gaseous fuel and water and supplying the reformed gas to the generator. A fuel tank stores the gaseous fuel in a liquid state by compressing the gaseous fuel and supplying the gaseous fuel to the reformer. A water supply device supplies the water to the reformer. The water supply device includes a container connected to the fuel tank and the reformer and contains the water and the gaseous fuel with a pressure. A separation layer is formed on the surface of the water in the container for blocking a contact of the gaseous fuel with the water.

Abstract: A reforming reaction unit for a reformer, and a method of manufacturing the same are disclosed. One embodiment of the reforming reaction unit includes: a cylindrical structure having a hollow space inside thereof; a cover surrounding the outer surface of the cylindrical structure; and a disc plate having a plurality of holes and directly contacting the inner surface of the cover at a predetermined position of the cylindrical structure in a lengthwise direction. The cylindrical structure includes an upper part above the disc plate. The upper part has a thread formed on its outer surface. The thread is in direct contact with the inner surface of the cover. The cylindrical structure also includes a lower part below the disc plate. The lower part has an outer surface spaced apart from the inner surface of the cover.

Abstract: Disclosed is a reformer for a fuel cell. The reformer for a fuel cell includes a reforming reactor generating reformed gas having abundant hydrogen gas by reforming fuel and steam and a standing shape of a water gas shift reactor coupled to the reforming reactor for lowering the concentration of carbon monoxide contained in the reformed gas. The water gas shift reactor has an opening. A pipe is coupled to the opening and has a portion located below the opening. Liquid water which may stay in the inside at the time that the operation stops can be drained out of the water gas shift reactor to prevent the water gas shift catalyst from being submerged in liquid water.

Abstract: The carbon monoxide oxidizing catalyst for a reformer of a fuel cell system according to the present invention includes an active material including Au—Ag alloy nano-particles, and a carrier supporting the active material.