Abstract: A fuel cell power generation system 100 includes a mechanism for detachably holding an adsorptive desulfurization section 5 for adsorbing a sulfur component in a hydrocarbon-based raw material; a reformer for generating hydrogen-containing gas from the raw material which has passed the adsorptive desulfurization section 5; a fuel cell 8 for generating power using the hydrogen-containing gas as a fuel; a raw material supply section 4 for controlling a flow rate of the raw material to be supplied to the adsorptive desulfurization section 5; and an operating control section 16 for controlling a behavior of the raw material supply section 4 and a behavior of the fuel cell 8.

Abstract: A hydrogen generator (100) includes: a desulfurizer (4) having a desulfurizing agent which removes by adsorption a sulfur compound in a raw material; a reformer (1) having a reforming catalyst which generates a hydrogen-containing gas from the raw material; a combustor (5) which heats the reformer (1); and an ignitor (103) which ignites the raw material in the combustor (5), is configured to start combustion of the combustor (5) by using the raw material passed through the desulfurizer (4), and further includes: an upper limit changing device (8) which changes an upper limit of an ignition confirmation time of the ignitor (103); and a change instruction receiving device (101) which receives a signal related to an instruction of the change.

Abstract: A power supply system according to the present invention includes a control device (110) which is configured such that if it is predicted that the sum of start-up power for a power generation system (101) and electric power consumed by an external electrical load (105) at start-up of the power generation system (101) and/or the sum of stopped-period power for the power generation system (101) and electric power consumed by the external electrical load (105) at stopping of power generation of the power generation system (101) exceed upper limit power, up to which an electric rate is kept to a relatively low unit price, and that the electric rate is to be changed to a relatively high unit price, then the control device (110) performs control of supplying electric power stored in an electrical storage unit (107) to at least one of the power generation system (101) and the external electrical load (105) in order to prevent the amount of electric power supplied from a power grid (104) from exceeding the upper limi

Abstract: A hydrogen generator (100a) includes: a heater (1) which combusts a mixture gas of combustion fuel and combustion air to generate a combustion gas; a preheat evaporator (6) which heats a raw material and water by the combustion gas generated by the heater to generate a mixture gas of the raw material and the water; a reformer (2) which generates a hydrogen-containing gas by causing the mixture gas generated by the preheat evaporator to pass through a reforming catalyst (2a) heated by the combustion gas; and a shift converter (3) which incorporates a shift catalyst (3a) which reduces, by a shift reaction, carbon monoxide contained in the hydrogen-containing gas generated by the reformer, and further includes a water trapping portion (7) which traps liquid water discharged from the preheat evaporator, and the hydrogen generator (100a) is configured to carry out heat exchange between the hydrogen-containing gas supplied from the reformer to the shift converter and the water in the water trapping portion.

Abstract: A hydrogen generator that is able to maintain an ability to supply a reformed gas containing less CO for a long time period while dealing with degradation of a catalytic activity of a shift reaction by a reliable and simple method, an operation method thereof, and a fuel cell system are provided. In a hydrogen generator (50) comprising a reformer (1), a shift converter (6), a water supply device (3A), a material feed device (2A), and a controller (12), the controller (12) is configured to count the number of times of start-up and/or stop of said hydrogen generator (50) and to increase a temperature or a S/C ratio of the reformed gas flowing in said shift converter (6) according to the counted number of times of start-up and/or stop.

Abstract: A hydrogen generator according to the invention comprises: a combustion gas passage (5) configured to flow combustion gas coming from a combustor; a preheat-evaporator (6) which is supplied with a material gas and water and configured to evaporate the water and heat the material gas by heat transmitted from the combustion gas passage and a carbon monoxide reducer (10) through partition a wall; a reformer (7) configured to generate reformed gas from the material gas and steam fed from the preheat-evaporator by using a reforming catalyst (8) and heat transmitted from the combustion gas passage through the partition wall; the carbon monoxide reducer (10) configured to remove carbon monoxide from the reformed gas fed from the reformer by a carbon monoxide removing catalyst (9); a cylindrical body (3) closed at both ends thereof having an internal space is divided by the partition walls (1), (2), (30), (47) to form the combustion gas passage, preheat-evaporator, reformer and carbon monoxide reducer within the cyli

Abstract: A hydrogen generating device including a temperature adjustment section 8 for controlling a temperature of a hydrogen-containing gas to be introduced from a reforming section 1 into carbon monoxide reducing sections 2 and 3, the temperature adjustment section 8 including: a heat exchange section 26 having an air path 11 for allowing a cooling air to pass therethrough; an air intake portion 10 having an opening for taking the cooling air into the air path 11; and an air discharging portion 12 having an opening for discharging the cooling air out of the air path 11, wherein the opening of the air intake portion 10 and that of the air discharging portion 12 are facing in a same direction, and the same direction is a vertically upward direction or a vertically downward direction.

Abstract: A hydrogen generator includes: a reformer configured to generate a hydrogen-containing gas by a reforming reaction between a raw material and water; a heater configured to combust at least a part of the hydrogen-containing gas to supply heat necessary for the reforming reaction to the reformer; a combustion detector configured to detect a combustion state of the heater; a raw material supplier configured to supply the raw material; a water supplier configured to supply the water; and an operation controller. When stopping the hydrogen generator, the operation controller causes the raw material supplier to stop operating, the water supplier to stop operating in a case where the combustion detector detects extinction of flame, and the raw material supplier to start operating to supply the raw material to the hydrogen generator in a case where the reforming temperature detector detects a temperature equal to or lower than a reference temperature.

Abstract: The present invention is a fuel cell system comprising: a hydrogen generator including a reformer which has a reforming catalyst and carries out a reforming reaction using the reforming catalyst to generate a hydrogen-containing gas from a raw material, a shift converter which has a shift catalyst and carries out a shift reaction using the shift catalyst to decrease carbon monoxide in the hydrogen-containing gas, and a first temperature detector which detects a temperature of the shift converter; a fuel cell which uses the hydrogen-containing gas delivered from the hydrogen generator, to generate electric power; and a control unit, wherein: the control unit does not start delivering the hydrogen-containing gas from the hydrogen generator to the fuel cell when at least the temperature of the shift converter detected by the first temperature detector is not a stable determination temperature or higher; and the stable determination temperature is lower than a control temperature of the shift converter at the tim

Abstract: An object is to provide a hydrogen generation apparatus in which water can be helically flow down in an evaporator without fail, a method for manufacturing the hydrogen generation apparatus, and a fuel cell system using the hydrogen generation apparatus. The hydrogen generation apparatus includes a reformer configured to generate a hydrogen-containing gas; an evaporator 8 which includes an inner tube 9 and an outer tube 10, and a deformed hollow helical member 18 helically interposed between the inner tube 9 and the outer tube 10 and which is configured to evaporate the water supplied to the reformer 8; and a heat source 2 configured to evaporate the water. The evaporator 8 is configured such that the water is supplied to a helical flow channel 8A defined by the inner tube 9, the outer tube 10, and the hollow helical member 18 and evaporated by the heat source 2.

Abstract: A fuel cell power generation system 100 for performing power generation using hydrogen-containing gas generated from a raw material containing a hydrocarbon component and an odorizer component includes a raw material supply section 4 for controlling a flow rate of the raw material; a water supply section 3 for supplying water; an adsorptive removal section 5 for causing the raw material to pass therethrough and adsorbing the odorizer component contained in the raw material; a reformer 1 for generating the hydrogen-containing gas by a reforming reaction of the raw material which has passed the adsorptive removal section and water supplied from the water supply section; a fuel cell 8 for performing power generation using the hydrogen-containing gas as a fuel; and an operating control section for, as an accumulated flow volume of the raw material supplied to the adsorptive removal section 5 from the raw material supply section 4 increases, decreasing the flow rate of the raw material to be supplied to the adsorp

Abstract: A hydrogen generator (100) of the present invention includes: a raw material supplying device (4) configured to supply a raw material containing a sulfur constituent; a hydrogen supplying device (7) configured to generate hydrogen by electrolysis of water; a hydro-desulfurizer (5) configured to remove the sulfur constituent of the raw material by using the hydrogen generated by the hydrogen supplying device (7), the raw material being supplied from the raw material supplying device (4); and a reformer (1) configured to generate a hydrogen-containing gas by a reforming reaction of the raw material from which the sulfur constituent is removed by the hydro-desulfurizer (5).

Abstract: Disclosed is a hydrogen generator which comprises a reformer (20) containing a reforming catalyst for generating a hydrogen-containing gas through the reforming reaction between a raw material and water, a reforming temperature detection unit (18) for detecting the temperature of a reforming catalyst, a heating unit (2) for burning at least a part of the hydrogen-containing gas to supply heat in a required amount for the reforming reaction to the reformer (20), a combustion detection unit (22) for detecting the burning state in the heating unit (2), a raw material supply unit (4) for supplying a raw material, a water supply unit (3) for supplying water, and an operation control unit (16).

Abstract: A method for operating a fuel cell system having a fuel cell equipped with an anode and a cathode includes the steps of generating electric power by allowing hydrogen gas supplied to the anode and oxygen gas supplied to the cathode to react electrochemically with each other, recovering water from water vapor discharged from at least one of the anode and cathode, storing recovered water in a water storing portion equipped with a tank having a closable drain opening, through which opening water stored in the tank is dischargeable to outside the fuel cell system, supplying water stored in the tank to a water utilizing means by a water supply portion, and making a decision whether or not to discharge the stored water to outside the fuel cell system through the drain opening in view of an increase in an amount of undesirable germs contained in water stored in the water storing portion.

Abstract: An energy supply system includes: an energy supply device (1a) configured to supply electric power and/or heat; and a controller (6) configured to set a first maximum operation time of a first specified period including a plurality of second specified periods, the first maximum operation time being an upper limit of an operation time of the energy supply device in the first specified period; calculate and set a second target maximum operation time of each of the second specified periods of the first specified period such that the operation time of the energy supply device in the first specified period does not exceed the first maximum operation time, the second target maximum operation time being a target value of an upper limit of the operation time of the energy supply device in the second specified period; and reconfigure the second target maximum operation time of a future second specified period of a certain first specified period based on a time in which the energy supply device has been actually operat

Abstract: An energy supply system comprises an energy supply device (1a) for supplying at least one of electric power and heat, and a controller (6) configured to set first maximum operation time which is an upper limit value of operation time of the energy supply device in a first specified period shorter than a guaranteed operation period of the energy supply device such that operation time of the energy supply device does not reach operation time life before the guaranteed operation period lapses, and calculate and set second maximum operation time which is an upper limit value of the operation time of the energy supply device in a second specified period shorter than the first specified period based on the set first maximum operation time such that the operation time of the energy supply device within the first specified period does not exceed the first maximum operation time.

Abstract: A hydrogen generator of the present invention includes: a raw material supplying device (4) configured to supply a raw material; a water supplying device (3) configured to supply water; an evaporator (23) configured to evaporate the water supplied from the water supplying device (3) to generate steam; a reformer (20) having a reforming catalyst which generates a hydrogen-containing gas by a reforming reaction using the raw material and the steam; a valve (12) disposed on a gas passage to cause the reformer (20) to be communicated with an atmosphere and block the reformer (20) from the atmosphere, the gas passage being located downstream of the reformer (20); and a controller (11) configured to stop supplying the water from the water supplying device (3), then continue to supply the raw material from the raw material supplying device (4) with the valve (12) open, and stop supplying the raw material from the raw material supplying device (4) and close the valve (12) before an inside of the reformer (20) is purg

Abstract: A fuel processing apparatus according to the present invention is a fuel processing apparatus 100 including a reformer 111, a raw material supply section 112, a moisture supply section 114, a heating section 116, a reforming temperature detection section 117 for detecting the temperature of a reforming catalyst, a shift converter 121, a shift temperature detection section 123, and a control section 200. When the apparatus is booted, the control section 200 activates the raw material supply section 111 to begin supplying a raw material to the reformer 111, and activates the heating section 116 to begin supplying heat to the reforming catalyst.

Abstract: The present invention is a fuel cell system comprising: a hydrogen generator including a reformer which has a reforming catalyst and carries out a reforming reaction using the reforming catalyst to generate a hydrogen-containing gas from a raw material, a shift converter which has a shift catalyst and carries out a shift reaction using the shift catalyst to decrease carbon monoxide in the hydrogen-containing gas, and a first temperature detector which detects a temperature of the shift converter; a fuel cell which uses the hydrogen-containing gas delivered from the hydrogen generator, to generate electric power; and a control unit, wherein: the control unit does not start delivering the hydrogen-containing gas from the hydrogen generator to the fuel cell when at least the temperature of the shift converter detected by the first temperature detector is not a stable determination temperature or higher; and the stable determination temperature is lower than a control temperature of the shift converter at the tim

Abstract: A fuel cell power generation system 100 includes a mechanism for detachably holding an adsorptive desulfurization section 5 for adsorbing a sulfur component in a hydrocarbon-based raw material; a reformer for generating hydrogen-containing gas from the raw material which has passed the adsorptive desulfurization section 5; a fuel cell 8 for generating power using the hydrogen-containing gas as a fuel; a raw material supply section 4 for controlling a flow rate of the raw material to be supplied to the adsorptive desulfurization section 5; and an operating control section for controlling a behavior of the raw material supply section 4 and a behavior of the fuel cell 8.