A cell stack in which a plurality of cells may have a cylindrical shape and may include gas flow passages may be arranged uprightly and may be electrically connected may include: a manifold configured to fix lower ends of the plurality of cells and supply gas to the gas flow passages of the plurality of cells, and a gas supply pipe configured to supply the gas to the manifold. The gas supply pipe may include one end connected to a gas supply portion and another end inserted into a first through hole provided in the manifold, and may be joined to the manifold via a first joining portion. The gas supply pipe may include a first protruding portion protruding toward an inner side of the gas supply pipe and located at a position corresponding to the first joining portion in any cross-section along an insertion direction of the gas supply pipe.

A tubular solid oxide fuel cell assembly includes at least two tubular solid oxide fuel cell units, at least one shared current collector and a retainer for retaining a section of the fuel cell units and shared current collector in close fitting relationship therewith.

A tubular solid oxide fuel cell assembly includes at least two tubular solid oxide fuel cell units, at least one shared current collector and a retainer for retaining a section of the fuel cell units and shared current collector in close fitting relationship therewith.

[Object] To provide a cell stack device, the power generation efficiency of which is improved, and a fuel cell module and a fuel cell device that include the cell stack device. [Solution] A cell stack device 1 includes a cell stack 2 that includes a plurality of fuel cells 3 electrically connected to one another and arranged, the fuel cells 3 that each includes a gas channel through which a reactant gas flows. In the cell stack device 1, the fuel cells 3 of the cell stack 2 are provided in the form of fuel cell groups that each include an arbitrary number of the fuel cells 3. In the cell stack device 1, the fuel cell groups are arranged such that average pressure loss values of the fuel cells 3 of the fuel cell groups increase sequentially from a central portion to an end portion side in a fuel cell 3 arrangement direction. Thus, the power generation efficiency of the cell stack device 1 can be improved.

A fuel cell system and method for using a peak shaving gas, the system including: a fuel inlet configured to receive fuel from a fuel source; a catalytic partial oxidation (CPOx) reactor configured to at least partially oxidize the fuel during startup of the system; a blower configured to provide air to the CPOx reactor; a gas analyzer configured to determine a composition of fuel provided to the CPOx reactor from the fuel inlet; an oxidation catalyst configured to reduce an O.sub.2 content of fuel received from the CPOx reactor; a reforming catalyst configured to partially reform fuel received from the oxidation catalyst; and a stack of fuel cells configured to generate electricity using fuel received from the reforming catalyst.

This fuel cell cartridge includes a plurality of cell stacks including a plurality of cells for forming a solid oxide fuel cell. A cell stack group including the plurality of cell stacks includes an inner cell stack group arranged in an inner region of a cell arrangement region and an outer cell stack group arranged in an outer region. The inner cell stack group and the outer cell stack group are connected in series and a current density of the outer cell stack group is configured to be higher than a current density of the inner cell stack group.

A fuel cell module may include: a cell stack device including a cell stack including an array of a plurality of fuel cells, a manifold which supplies a fuel gas to each of the fuel cells, and a reformer which reforms a raw fuel; an oxygen-containing gas flow channel through which the oxygen-containing gas flows; an oxygen-containing gas introduction plate which supplies the oxygen-containing gas to each of the plurality of fuel cells; a housing including a box body of which one side is opened to provide an opening and a lid (closed plate) which closes the opening; a gas pipe joint, an ignition heater, a thermocouple, etc. which are a plurality of insertion members inserted from an outside of the housing into an accommodation chamber, the respective insertion members being inserted through one surface (lid surface) of the housing.

A cell stack device may include a cell stack comprising a plurality of cells, a manifold configured to supply a reaction gas to the plurality of cells, and a reaction gas supply pipe connected to the manifold. The manifold may include an insertion portion configured to connect the reaction gas supply pipe to the manifold and a first joining portion configured to join the insertion portion and the reaction gas supply pipe. A module may include the cell stack device contained in a housing container. A module housing device may include the module, an auxiliary device configured to operate the module, and an external casing configured to contain the module and the auxiliary device therein.

A cell including: a body having a first end portion and a second end portion; a first electrode layer electrically connected to the body; a solid electrolyte layer located on the first electrode layer; and a second electrode layer located on the solid electrolyte layer, wherein the body includes a flared gas-flow passage passing through the body from the first end portion to second end portion; and diameters of opposing end portions of the flared gas-flow passage are greater than a diameter of the flared gas-flow passage at a central portion between the opposing end portions.

A heat insulation structure for a high-temperature reaction room includes a heat insulating body surrounding the reaction room. The heat insulating body contains a binder component including a metal element and is arranged so as to face an insulating film disposed on a cell stack. Transfer of metal ions originating in the metal element from the heat insulating body toward the insulating film is suppressed by a metal ion transfer suppression means.