Abstract: Disclosed are power generation apparatuses. An exemplary power generation apparatus (1) is configured such that water vapor generated in a steam generator (2) is supplied to a scroll expander (3) to drive the scroll expander, wherein: a condensation device (5) is arranged in a discharge path (12) downstream of the scroll expander, the condensation device being configured to mix water vapor having passed through the scroll expander directly with cooling water to condense the water vapor; and the condensation device includes a control unit (10) that performs a control of adjusting the amount of cooling water supply so as to obtain condensed water having a predetermined temperature.

Abstract: An on-vehicle relay device that is connected to a first on-vehicle device and a second on-vehicle device via an on-vehicle network, and relays a message transmitted from the first on-vehicle device to the second on-vehicle device, includes a processor configured to receive a permission request for transmission of a first message from the first on-vehicle device, determine whether the total of the usage rate of the bandwidth of the on-vehicle network used by at least one message already permitted to be transmitted via the on-vehicle network, and the usage rate of the bandwidth of the on-vehicle network used by the first message is equal to or smaller than a predetermined threshold value, and send a reply that permits transmission of the first message, to the first on-vehicle device, when the sum is equal to or smaller than the predetermined threshold value.

Abstract: An electric storage device has an electrode body and a housing body. The electrode body has a plurality of positive plates and a plurality of negative plates. The positive plates and the negative plates are alternately stacked on each other via separators. The housing body houses the electrode body together with an ion conductor. The electric storage device is provided with a magnetic field generating unit that generates magnetic force lines in a certain direction.

Abstract: A wet-type multi plate clutch capable of being used for a transmission in an automobile. A clutch pack 50 is provided with a plurality of drive plate 52 and a plurality of driven plates 54. The drive plates 52 have single surfaces on which clutch facings 55 are fixed and opposed surfaces on which annular grooves 58 along entire peripheral lengths are formed. The driven plates 54 have single surfaces on which clutch facings 56 are fixed and opposed surfaces on which annular grooves 59 along entire peripheral lengths are formed. The sliding surfaces of the drive plates 52 and the driven plates 54 are arranged between the clutch facings 55 and 56, which are axially adjacent with each other.

Abstract: An energy storage device before pre-doping includes positive electrodes, negative electrodes, separators, a cover, an electrolyte solution, a positive terminal, a negative terminal, and pre-doping metal foil. Each of the positive electrodes and the negative electrodes respectively include: positive collector foil and negative collector foil each having holes; and a positive active-material layer and a negative active-material layer arranged on at least one side of the collector foil. Either one or both of the positive electrodes and the negative electrodes include a pre-doping-targeted electrode, in which the pre-doping metal foil is arranged in direct contact with the surface of the active-material layer, and a non-arrangement part, in which the pre-doping metal foil is not arranged, is formed in at least part of the outer periphery of the active-material layer.

Abstract: An electrolyte layer-anode composite member for a fuel cell includes a solid electrolyte layer containing an ionically conductive metal oxide M1, a first anode layer containing an ionically conductive metal oxide M2 and nickel oxide, and a second anode layer interposed between the solid electrolyte layer and the first anode layer and containing an ionically conductive metal oxide M3 and nickel oxide. A volume content Cn1 of the nickel oxide in the first anode layer and a volume content Cn2 of the nickel oxide in the second anode layer satisfy the relation Cn1<Cn2.

Abstract: This invention relates to a thermoelectric material constituted of nanostructures and a thermoelectric element and an optical sensor including the same, as well as to a method for manufacturing a thermoelectric material constituted of nanostructures. An object of the present disclosure is to achieve better thermoelectric characteristics of the thermoelectric material containing nanoparticles. The thermoelectric material includes a first material having a band gap and a second material different from the first material. The thermoelectric material contains a plurality of nanoparticles distributed in a base material which is a mixture of the first material and the second material. A composition of the second material in the thermoelectric material is not lower than 0.01 atomic % and not higher than 2.0 atomic % of the thermoelectric material.

Abstract: Provided is a lithium ion capacitor that can retain a capacity under a high temperature environment and has small increase in internal resistance while using an aqueous binder for a positive electrode. A lithium ion capacitor includes: a positive electrode; a negative electrode; and an electrolytic solution contacting the positive electrode and the negative electrode. The electrolytic solution includes an organic solvent and a lithium salt electrolyte having an imide structure; the positive electrode includes a collector foil and a positive electrode active material; and the positive electrode active material is held onto the collector foil through a binder including a polymer having a RED value to the electrolytic solution of more than 1, the RED value representing a relative energy difference with respect to the electrolytic solution based on Hansen solubility parameters.

Abstract: Disclosed are power generation apparatuses. An exemplary power generation apparatus (1) is configured such that water vapor generated in a steam generator (2) is supplied to a scroll expander (3) to drive the scroll expander, wherein: a condensation device (5) is arranged in a discharge path (12) downstream of the scroll expander, the condensation device being configured to mix water vapor having passed through the scroll expander directly with cooling water to condense the water vapor; and the condensation device includes a control unit (10) that performs a control of adjusting the amount of cooling water supply so as to obtain condensed water having a predetermined temperature.

Abstract: An energy storage device before pre-doping includes positive electrodes, negative electrodes, separators, a cover, an electrolyte solution, a positive terminal, a negative terminal, and pre-doping metal foil. Each of the positive electrodes and the negative electrodes respectively include: positive collector foil and negative collector foil each having holes; and a positive active-material layer and a negative active-material layer arranged on at least one side of the collector foil. Either one or both of the positive electrodes and the negative electrodes include a pre-doping-targeted electrode, in which the pre-doping metal foil is arranged in direct contact with the surface of the active-material layer, and a non-arrangement part, in which the pre-doping metal foil is not arranged, is formed in at least part of the outer periphery of the active-material layer.

Abstract: A diode having excellent switching characteristics is provided. A diode includes a silicon carbide substrate, a stop layer, a drift layer, a guard ring, a Schottky electrode, an ohmic electrode, and a surface protecting film. At a measurement temperature of 25° C., a product R•Q of a forward ON resistance R of the diode and response charges Q of the diode satisfies relation of R•Q?0.24×Vblocking2. The ON resistance R is found from forward current-voltage characteristics of the diode. A reverse blocking voltage Vblocking is defined as a reverse voltage which produces breakdown of the diode. The response charges Q are found by integrating a capacitance (C) obtained in reverse capacitance-voltage characteristics of the diode in a range from 0 V to Vblocking.

Abstract: An electric storage device has an electrode body and a housing body. The electrode body has a plurality of positive plates and a plurality of negative plates. The positive plates and the negative plates are alternately stacked on each other via separators. The housing body houses the electrode body together with an ion conductor. The electric storage device is provided with a magnetic field generating unit that generates magnetic force lines in a certain direction.

Abstract: Provided is a lithium ion capacitor that can retain a capacity under a high temperature environment and has small increase in internal resistance while using an aqueous binder for a positive electrode. A lithium ion capacitor includes: a positive electrode; a negative electrode; and an electrolytic solution contacting the positive electrode and the negative electrode. The electrolytic solution includes an organic solvent and a lithium salt electrolyte having an imide structure; the positive electrode includes a collector foil and a positive electrode active material; and the positive electrode active material is held onto the collector foil through a binder including a polymer having a RED value to the electrolytic solution of more than 1, the RED value representing a relative energy difference with respect to the electrolytic solution based on Hansen solubility parameters.

Abstract: A Group III nitride semiconductor device comprises: a Group III nitride semiconductor layer having a primary surface, inclined with respect to a c-plane of the Group III nitride semiconductor at an angle in a range of 50 degrees or more and 80 degrees or less, of a Group III nitride semiconductor; a p-type Group III nitride semiconductor laminate including first to third p-type Group III nitride semiconductor layers, the first to third p-type Group III nitride semiconductor layers being provided on the primary surface of the Group III nitride semiconductor layer, the first and third p-type Group III nitride semiconductor layers sandwiching the second p-type Group III nitride semiconductor layer such that the second p-type Group III nitride semiconductor layer incorporates strain; and an electrode provided on the p-type Group III nitride semiconductor laminate. The electrode is in contact with the first p-type Group III nitride semiconductor layer.

Abstract: There is provided a composite material for a fuel cell, in which in the case where an electrolyte-anode laminate is co-fired, the composite material is capable of inhibiting a decrease in the ion conduction performance of a solid electrolyte layer to enhance the power generation performance of the fuel cell. A composite material 1 for a fuel cell includes a solid electrolyte layer 3 and an anode layer 2 stacked on the solid electrolyte layer, in which the solid electrolyte layer is composed of an ionic conductor in which the A-site of a perovskite structure is occupied by at least one of barium (Ba) and strontium (Sr) and tetravalent cations in the B-sites are partially replaced with a trivalent rare-earth element, the anode layer contains an electrolyte component having the same composition as the solid electrolyte layer, a nickel (Ni) catalyst, and an additive containing a rare-earth element, the additive being located at least at an interfacial portion with the solid electrolyte layer.

Abstract: A Group III nitride semiconductor device comprises: a Group III nitride semiconductor layer having a primary surface, inclined with respect to a c-plane of the Group III nitride semiconductor at an angle in a range of 50 degrees or more and 80 degrees or less, of a Group III nitride semiconductor; a p-type Group III nitride semiconductor laminate including first to third p-type Group III nitride semiconductor layers, the first to third p-type Group III nitride semiconductor layers being provided on the primary surface of the Group III nitride semiconductor layer, the first and third p-type Group III nitride semiconductor layers sandwiching the second p-type Group III nitride semiconductor layer such that the second p-type Group III nitride semiconductor layer incorporates strain; and an electrode provided on the p-type Group III nitride semiconductor laminate. The electrode is in contact with the first p-type Group III nitride semiconductor layer.

Abstract: A diode having excellent switching characteristics is provided. A diode includes a silicon carbide substrate, a stop layer, a drift layer, a guard ring, a Schottky electrode, an ohmic electrode, and a surface protecting film. At a measurement temperature of 25° C., a product R•Q of a forward ON resistance R of the diode and response charges Q of the diode satisfies relation of R•Q?0.24×Vblocking2. The ON resistance R is found from forward current-voltage characteristics of the diode. A reverse blocking voltage Vblocking is defined as a reverse voltage which produces breakdown of the diode. The response charges Q are found by integrating a capacitance (C) obtained in reverse capacitance-voltage characteristics of the diode in a range from 0 V to Vblocking.

Abstract: A degree-of-dispersion inspecting apparatus accurately quantifies the degree of dispersion of particles of an electricity storage material based on in-plane uniformityand void size uniformity, which are obtained from an image of a coating film of the electricity storage material. The in-plane uniformity is a macroscopic value based on the ratio of voids between the particles in the electricity storage material, and the void size uniformity is a microscopic value based on values equivalent to the sizes of the voids between the particles in the electricity storage material. This allows the degree of dispersion of the particles of the electricity storage material to be accurately quantified even if the particles of the electricity storage material are in contact with each other or vary in size.

Abstract: A kneading device includes an index setting portion that sets an index for kneading based on a motion energy of particles of an electricity storage material, a mean free path of the particles of the electricity storage material, and a kneading time for the electricity storage material, a condition setting portion that sets a condition for the kneading based on the set index for the kneading, and a kneading control portion that controls the kneading of the electricity storage material in accordance with the set condition for the kneading.

Abstract: A dimension measuring device 100 in accordance with the present invention includes an end face following mechanism 1 that butts against an end face E of a long material, a dimension measuring mechanism 2 for measuring the dimensions of the long material, and a pushingly moving mechanism 3 for pushingly moving the end face following mechanism toward the end face of the long material. The end face following mechanism includes a plurality of contact sensors for detecting a contact state, and is turnable around two axes intersecting at right angles with each other. The pushingly moving mechanism pushingly moves the end face following mechanism into the state in which the plurality of contact sensors detect that the end face following mechanism butts against the end face of the long material.