Abstract: A bipolar plate arranged to face an electrode along which electrolyte is circulated, the bipolar plate includes a flow passage that is provided on at least one of front and back surfaces of the bipolar plate and along which the electrolyte is circulated. The flow passage provided on the at least one of the front and back surfaces of the bipolar plate includes an introduction path along which the electrolyte is introduced and a discharge path that does not communicate with and is independent of the introduction path and along which the electrolyte is discharged. At least one of the introduction path and the discharge path includes an inclined groove that non-orthogonally intersects a long side and a short side of an imaginary rectangle that includes an outer edge of the bipolar plate.

Abstract: An electrode for a redox flow battery includes a substrate, a conductive portion applied to a surface of the substrate, and a catalytic portion held by the conductive portion, the conductive portion containing one or more types of elements selected from the group ?1 consisting of Sn, Ti, Ta, Ce, In, and Zn, the catalytic portion containing one or more types of elements selected from the group ? consisting of Ru, Ir, Pd, Pt, Rh, and Au.

Abstract: A redox flow battery includes: a battery cell including a positive electrode, a negative electrode, and a membrane interposed between the positive electrode and the negative electrode; a pair of cell frames each including a bipolar plate and a frame body surrounding a circumferential edge of the bipolar plate, the pair of cell frames holding the battery cell therebetween; a positive electrolyte supplied to the positive electrode; and a negative electrolyte supplied to the negative electrode. The bipolar plate is formed of pure titanium or a titanium alloy, and the negative electrolyte has an oxidation-reduction potential of 0.0 V or higher relative to a standard hydrogen electrode.

Abstract: A battery is provided which includes at least one pair of cell frames stacked together and each including a frame body and a bipolar plate, the frame body having a manifold serving as a flow path for a battery fluid, the bipolar plate being disposed inside the frame body; a positive electrode and a negative electrode; and a membrane having a through hole corresponding to the manifold. The battery includes a sealing member including an annular base portion and bifurcated annular leg portions. The annular base portion is disposed along an inner periphery of the through hole, and the bifurcated annular leg portions extend from the annular base portion toward the outside of the through hole in such a manner that the membrane is sandwiched therebetween. The sealing member is interposed between the frame bodies stacked together.

Abstract: An electrode for a redox flow battery includes a substrate, a conductive portion applied to a surface of the substrate, and a catalytic portion held by the conductive portion, the conductive portion containing one or more types of elements selected from the group ?1 consisting of Sn, Ti, Ta, Ce, In, and Zn, the catalytic portion containing one or more types of elements selected from the group ? consisting of Ru, Ir, Pd, Pt, Rh, and Au.

Abstract: A bipolar plate arranged to face an electrode along which electrolyte is circulated, the bipolar plate includes a flow passage that is provided on at least one of front and back surfaces of the bipolar plate and along which the electrolyte is circulated. The flow passage provided on the at least one of the front and back surfaces of the bipolar plate includes an introduction path along which the electrolyte is introduced and a discharge path that does not communicate with and is independent of the introduction path and along which the electrolyte is discharged. At least one of the introduction path and the discharge path includes an inclined groove that non-orthogonally intersects a long side and a short side of an imaginary rectangle that includes an outer edge of the bipolar plate.

Abstract: A battery is provided which includes at least one pair of cell frames stacked together and each including a frame body and a bipolar plate, the frame body having a manifold serving as a flow path for a battery fluid, the bipolar plate being disposed inside the frame body; a positive electrode and a negative electrode; and a membrane having a through hole corresponding to the manifold. The battery includes a sealing member including an annular base portion and bifurcated annular leg portions. The annular base portion is disposed along an inner periphery of the through hole, and the bifurcated annular leg portions extend from the annular base portion toward the outside of the through hole in such a manner that the membrane is sandwiched therebetween. The sealing member is interposed between the frame bodies stacked together.

Abstract: An electrode is constituted by a sheet-shaped porous body and used in an electrolyte-circulating battery that performs charging and discharging by circulating an electrolyte. Assuming that a portion of a side surface of the electrode that is adjacent to an inlet for the electrolyte when the electrode is installed in the electrolyte-circulating battery is an inlet end surface and a portion of the side surface of the electrode that is adjacent to an outlet for the electrolyte when the electrode is installed in the electrolyte-circulating battery is an outlet end surface, the electrode includes a first flow channel that is connected to the inlet end surface and extends toward the outlet end surface and a second flow channel that is connected to the outlet end surface and extends toward the inlet end surface. The first flow channel and the second flow channel do not directly communicate with each other.

Abstract: A flow battery includes a cell, a bipolar plate which is in contact with one of a positive electrode and a negative electrode constituting the cell, a current collector plate which has a terminal portion that is led out to the outside of the cell and is electrically connected to the bipolar plate, and a supply/discharge plate which is stacked on the current collector plate and supplies and discharges electrolytes to and from the cell. When the side of the supply/discharge plate facing the current collector plate is regarded as a front surface and the side opposite thereto is regarded as a back surface, the supply/discharge plate has an insertion hole which passes between the front surface and the back surface thereof and into which the terminal portion is inserted, and the terminal portion passes through the insertion hole and extends from the front surface side to the back surface side of the supply/discharge plate to be led out.

Abstract: Provided is a battery cell stack in which the electrical resistance between a current collector plate and an end bipolar plate is unlikely to increase when charging and discharging are repeated. A battery cell stack includes a current collector plate electrically connected to each of a pair of end bipolar plates located at both ends in the stacking direction. In the battery cell stack, two members in contact with each other between the current collector plate and the end bipolar plate are made of materials such that, when an accelerated test satisfying the following conditions 1 to 3 is performed, the electrical resistance value between the current collector plate and the end bipolar plate after the accelerated test is 1.

Abstract: Provided is a battery cell stack in which the electrical resistance between a current collector plate and an end bipolar plate is unlikely to increase when charging and discharging are repeated. A battery cell stack includes a current collector plate electrically connected to each of a pair of end bipolar plates located at both ends in the stacking direction. In the battery cell stack, two members in contact with each other between the current collector plate and the end bipolar plate are made of materials such that, when an accelerated test satisfying the following conditions 1 to 3 is performed, the electrical resistance value between the current collector plate and the end bipolar plate after the accelerated test is 1.

Abstract: A flow battery includes a cell, a bipolar plate which is in contact with one of a positive electrode and a negative electrode constituting the cell, a current collector plate which has a terminal portion that is led out to the outside of the cell and is electrically connected to the bipolar plate, and a supply/discharge plate which is stacked on the current collector plate and supplies and discharges electrolytes to and from the cell. When the side of the supply/discharge plate facing the current collector plate is regarded as a front surface and the side opposite thereto is regarded as a back surface, the supply/discharge plate has an insertion hole which passes between the front surface and the back surface thereof and into which the terminal portion is inserted, and the terminal portion passes through the insertion hole and extends from the front surface side to the back surface side of the supply/discharge plate to be led out.

Abstract: An easy-to-assemble battery sealing structure is provided. A cell frame includes a battery plate-like member (bipolar plate), a pair of frames for holding a peripheral portion of bipolar plate therebetween and pressing the peripheral portion from the front and the rear, and an annular packing made of an elastic material. Frames are provided with an annular groove between respective surfaces of the frames facing each other, for accommodating the peripheral portion of bipolar plate. Packing is mounted on the peripheral portion of bipolar plate, arranged in annular groove, and press-contacted between frames and the peripheral portion of bipolar plate. Packing includes a pair of legs for holding the peripheral portion of bipolar plate therebetween, and a base connecting legs together.

Abstract: This invention provides a cell stack for a redox flow battery that can provide battery efficiencies with high reliability over a long term, without any adhesive bonding between a bipolar plate and electrodes. In the cell stack 1 for the redox flow battery of a cell frame 2, electrodes 3, 4 and a membrane 5 being stacked in layers, the cell frame 2 comprises a frame 2A and a bipolar plate 9 arranged inside of the frame 2A, and the electrodes 3, 4 are put into close contact with the bipolar plate 9 by a clamping force, without being adhesively bonded to the bipolar plate 9. It is preferable that when the electrodes 3, 4 are compressed to a thickness corresponding to a level difference between the frame 2A and the bipolar plate 9, repulsive force of the electrodes is in the range of more than 15 kPa to less than 150 kPa (more than 0.153 kgf/cm2 to less than 1.53 kgf/cm2).

Abstract: An easy-to-assemble battery sealing structure is provided. A cell frame includes a battery plate-like member (bipolar plate), a pair of frames for holding a peripheral portion of bipolar plate therebetween and pressing the peripheral portion from the front and the rear, and an annular packing made of an elastic material. Frames are provided with an annular groove between respective surfaces of the frames facing each other, for accommodating the peripheral portion of bipolar plate. Packing is mounted on the peripheral portion of bipolar plate, arranged in annular groove, and press-contacted between frames and the peripheral portion of bipolar plate. Packing includes a pair of legs for holding the peripheral portion of bipolar plate therebetween, and a base connecting legs together.

Abstract: A roller wheel for a track-type travelling vehicle is disposed on a non-ground-engaging side of a track and supported by a vehicle body frame. The roller wheel includes a shaft, a roller assembly and a bearing. The shaft is supported by the vehicle body frame. The roller assembly is disposed on an outer periphery of the shaft. The bearing allows the roller assembly to be rotatably supported by the shaft therethrough. The roller assembly includes a tubular inner roller shell disposed closer to the vehicle body frame, and a tubular outer roller shell disposed outwards of the inner roller, the tubular outer roller shell being coupled to the inner roller shell by a straddle fitting structure.

Abstract: This invention provides a cell frame for a redox flow battery that prevents leakage of electrolyte out of the cell frame and also provides a good workability in assembling the redox flow battery. Also, this invention provides a redox flow battery using the cell frame. In the cell frame 30 for the redox flow battery 30 comprising a bipolar plate 21 and a frame 31 fitted around a periphery of the bipolar plate 21, the frame 31 has, on each side thereof, an inner seal and an outer seal to press-contact with a membrane and also seal electrolyte. The frame 31 has, on each side thereof, an inner seal groove 34 and an outer seal groove 35 for placing therein the inner seal and the outer seal, respectively, to prevent the electrolyte from leaking out, and O-rings are placed in the respective seal grooves.

Abstract: This invention provides a cell frame for a redox flow battery that prevents leakage of electrolyte out of the cell frame and also provides a good workability in assembling the redox flow battery. Also, this invention provides a redox flow battery using the cell frame. In the cell frame 30 for the redox flow battery 30 comprising a bipolar plate 21 and a frame 31 fitted around a periphery of the bipolar plate 21, the frame 31 has, on each side thereof, an inner seal and an outer seal to press-contact with a membrane and also seal electrolyte. The frame 31 has, on each side thereof, an inner seal groove 34 and an outer seal groove 35 for placing therein the inner seal and the outer seal, respectively, to prevent the electrolyte from leaking out, and O-rings are placed in the respective seal grooves.

Abstract: The present invention provides electrolyte that can suppress reduction of battery efficiencies and capacities with increased cycles of charge/discharge of the battery, a method for producing the same, and a redox flow battery using the same electrolyte. The redox flow battery uses the electrolyte having a NH4 content of not more than 20 ppm and a relation of Si concentration (ppm)×electrolyte quantity (m3)/electrode area (m2) of less than 5 ppm·m3/m2. By limiting a quantity of contaminants in the electrolyte, a clogging of carbon electrodes to cause reduction of the battery performances with increased charge/discharge operations can be suppressed.