Abstract: A fuel cell separator is pressed so that one side thereof defines a gas flow channel and that the other side thereof defines a coolant flow channel. A width dG and a cross-sectional area SG of the gas flow channel and a width dW and a cross-sectional area Sw of the coolant flow channel satisfy a relationship: dG≧dW or a relationship: SG≧SW.

Abstract: Separators for unit cells of a fuel cell each have a plurality of through holes extending therethrough and a recessed portion formed in a surface thereof. In a fuel cell incorporating such separators, the recessed portion of each separator forms an in-cell oxidative gas passage, together with an adjacent cathode. An oxidative gas, supplied from an external device into the fuel cell, is distributed from an oxidative gas supply manifold formed by holes of the separators, to the in-cell oxidative gas passages. The oxidative gas is then collected in an oxidative gas discharge manifold formed by holes of the separators, and conveyed out of the fuel cell by the discharge manifold. During the passage through each in-cell oxidative gas passage, the oxidative gas flows via an oxidative gas transit manifold formed by holes of the separators.

Abstract: A fuel cell includes a separator including a first member made from metal and a second member made from synthetic resin. The separator has a power generating portion corresponding portion including a gas passage portion and opposing portions located on opposite sides of the power generating portion corresponding portion. A manifold portion is formed in the opposing portions. The manifold portion is offset from the gas passage portion. A gas passage connecting portion is formed in the second member and fluidly connects the manifold portion and the gas passage portion. A gas flow adjusting portion is formed for directing a direction of a gas flow at the gas passage connecting portion to a direction perpendicular to a direction connecting the opposing portions and making a gas flow into and from the gas passage portion uniform in the direction perpendicular to a direction connecting the opposing portions.

Abstract: A separator for a fuel cell, where the fuel cell has two separators and an MEA sandwiched by the metal separators. The separator has a portion corresponding to the power generating portion of the MEA and opposing portions located on opposite sides of the power generating portion. The separator has a gas passage at a first surface and a coolant passage at a second, opposite surface. The gas passage has an odd number of straight-extending portions and an even number of U-turn portions and extends between the opposing portions by U-turning twice or more. The coolant passage extends straight between the opposing portions without U-turning.

Abstract: Separators for unit cells of a fuel cell each have a plurality of through holes extending therethrough and a recessed portion formed in a surface thereof. In a fuel cell incorporating such separators, the recessed portion of each separator forms an in-cell oxidative gas passage, together with an adjacent cathode. An oxidative gas, supplied from an external device into the fuel cell, is distributed from an oxidative gas supply manifold formed by holes of the separators, to the in-cell oxidative gas passages. The oxidative gas is then collected in an oxidative gas discharge manifold formed by holes of the separators, and conveyed out of the fuel cell by the discharge manifold. During the passage through each in-cell oxidative gas passage, the oxidative gas flows via an oxidative gas transit manifold formed by holes of the separators.

Abstract: Separators for unit cells of a fuel cell each have a plurality of through holes extending therethrough and a recessed portion formed in a surface thereof. In a fuel cell incorporating such separators, the recessed portion of each separator forms an in-cell oxidative gas passage, together with an adjacent cathode. An oxidative gas, supplied from an external device into the fuel cell, is distributed from an oxidative gas supply manifold formed by holes of the separators, to the in-cell oxidative gas passages. The oxidative gas is then collected in an oxidative gas discharge manifold formed by holes of the separators, and conveyed out of the fuel cell by the discharge manifold. During the passage through each in-cell oxidative gas passage, the oxidative gas flows via an oxidative gas transit manifold formed by holes of the separators.

Abstract: An x-ray CT solid-state detector provided with detector blocks each having a substrate, a photodiode array secured to the substrate and a scintillator array secured to the photodiode array, and with a collimator device having a plurality of collimator plates secured to a support body, and arranged such that transmitted x-rays obtained by irradiating a fan-shape x-ray beam from an x-ray source onto a subject to be tested, are guided to the detector blocks through the collimator device. There is secured, to each substrate, a groove plate having at a predetermined position a groove into which a collimator plate is to be fitted. The scintillator and photodiode arrays are secured to each substrate with a predetermined positional relationship between the scintillator and photodiode arrays and the groove plate maintained. Each detector block and the collimator device are fixed to each other with a collimator plate fitted in the groove of the groove plate.

Abstract: A detector for an x-ray tomography apparatus has a plurality of detection elements arranged near an x-ray incident position in an array transverse to the slice direction. Each detection element is formed with a phosphorescent element for converting an incident radiation beam into light and a photoelectric conversion element for converting light from the phosphorescent element into an electrical signal. The phosphorescent element is shorter in the slice direction than the sensitive region of the photoelectric conversion element such that radiation reaching an edge area of the phosphorescent element can also be detected within a sensitive region of the photoelectric conversion element and generation of virtual and false images can be prevented.