RU2001128887A

RU2001128887A - BATTERY BATTERY, DEVICE CONTAINING BATTERY BATTERY, METHOD FOR LOCALLY DISTRIBUTED ELECTRIC POWER PRODUCTION AND ELECTRIC POWER PRODUCTION DEVICE IS SPECIFIED

Info

Publication number: RU2001128887A
Application number: RU2001128887/09A
Authority: RU
Inventors: Казуо ЦУЦУМИ; Тосио АЦУТА; Тиканори КУМАГАИ; Мицухару КИСИМОТО; Ацуси ЦУЦУМИ
Original assignee: Кавасаки Дзюкогио Кабусики Кайся
Priority date: 1999-03-29
Filing date: 2000-03-27
Publication date: 2003-07-20

Claims

1. A battery containing two containers connected by an element installed between them that allows the passage of ions and prevents the passage of electrons, a powder active material filling one of the containers and suspended in an electrolyte solution to emit electrons, and a powder active material filling the other container and suspended in an electrolyte solution to absorb electrons, while in two containers conductive current collectors are placed in contact with powder active materials and.

2. The battery according to claim 1, characterized in that it contains at least one means of fluidization and dispersion of the fluid and mixing means using liquid or gas to fluidize the powdered active materials in electrolyte solutions in two containers, these funds are connected to two containers or placed in two containers to ensure effective contact between powder active materials and between powder active materials and current collectors.

3. The battery according to claim 1 or 2, characterized in that the current collectors in contact with the powder active materials are in the form of a rod, or plate, or tube.

4. The battery according to claim 2 or 3, characterized in that the current collectors in contact with the powder active materials serve at least as a means of fluidization and dispersion of the fluid and mixing means using a liquid or gas to fluidize the powder active materials in electrolyte solutions in containers.

5. The battery according to claims 1, 2, 3 or 4, characterized in that heat exchangers are placed in two containers to maintain a constant reaction temperature in the battery.

6. The battery according to claim 5, characterized in that the heat transmitters are selected from the group consisting of tubular current collectors and plate current collectors in contact with powder active materials.

7. The battery according to claims 1 to 6, characterized in that it contains a means for removing powdered active materials from two containers that have lost their properties and a means for introducing powdered active materials into containers, said means are connected to said two containers.

8. The battery according to claim 7, characterized in that it contains at least either a means for recovering the removed powdered active materials or a means of replenishing the powdered active materials, at least one of said means is connected to a removal means for supplying the recovered or replenished powder active materials from the feed.

9. The battery according to claim 7 or 8, characterized in that it contains a reaction means for recharging the discharged powder active materials due to a thermal reaction or chemical reaction, which is connected to a removal means and is intended to supply recharged powder active materials to said containers from the supply means .

10. The battery according to any one of claims 1 to 9, characterized in that the powder active material on the anode side is a powder absorbing hydrogen alloy, and the powder active material on the cathode side is a powder nickel hydroxide.

11. The battery according to any one of claims 2 to 9, characterized in that the powder active material on the anode side is a powder absorbing hydrogen alloy, the gas introduced into the fluidization and dispersion medium on the anode side is hydrogen, the powder active material on the cathode the side is nickel hydroxide powder, and the gas introduced into the fluidization and dispersion means of the fluid on the cathode side is oxygen or air.

12. A three-dimensional layered type battery containing many pairs of individual batteries, each of which contains a pair of battery cells connected by an element installed between them that allows the passage of ions but prevents the passage of electrons, a powder active material filling one of the cells and suspended in solution an electrolyte filling one of the battery cells to emit electrons; a powdered active material filling the other cell and suspended in an elec a roller filling another battery cell to absorb electrons, wherein a plurality of pairs of batteries are connected in series with conductive collector cells arranged in such a way that they delimit the dividing walls of the respective battery cells and are in contact with powder active materials, while the battery cells are opposite the sides have current collectors that are in contact with powder active materials and accordingly function as a cathode and anode.

13. The three-dimensional battery according to claim 12, characterized in that in each of the battery cells there is placed a mixing means for fluidizing the powder active material suspended in an electrolyte solution.

14. The three-dimensional battery according to item 12 or 13, characterized in that the conductive pins are installed integral with the collector elements or current collectors, and these pins protrude from them inside the corresponding battery cells.

15. The three-dimensional battery according to item 13, wherein the mixing means is also designed to stop the fluidization of the powdered active material to reduce the amount of energy coming from the battery.

16. Three-dimensional battery according to any one of paragraphs.12-15, characterized in that the powdered active material emitting electrons is a material selected from the group consisting of a hydrogen-absorbing alloy of cadmium, iron, zinc, lead.

17. The three-dimensional battery according to any one of paragraphs.12-15, characterized in that the powdered active material that absorbs electrons is a material selected from the group consisting of nickel hydroxide, lead dioxide, manganese dioxide.

18. A device containing a battery of three-dimensional design, which contains two containers connected by an element installed between them, which allows the passage of ions and prevents the passage of electrons, a powdered active material filling one of the containers and suspended in an electrolyte solution in one container, for emitting electrons powder active material filling another container and suspended in an electrolyte solution in another container for electron absorption, in two containers s installed conductive current collectors in contact with the powdered active materials, and the device performs the function of rechargeable / dischargeable power storage equipment.

19. The device according to p. 18, characterized in that it contains at least one means of fluidization and dispersion of the fluid and mixing means using liquid or gas to fluidize the powdered active materials suspended in electrolyte solutions in two containers, these funds are connected to two capacities or are provided in two capacities.

20. The device according to p. 18 or 19, characterized in that the device is rotating, using the energy stored in the battery as an energy source.

21. The device according to p. 18 or 19, characterized in that the device is a movable body using the energy stored in the battery as an energy source.

22. The device according to p. 18 or 19, characterized in that the device is a means for supplying energy stored in the battery to other equipment.

23. The device according to p. 18 or 19, characterized in that the device is a device for converting the energy stored in the battery into light energy, kinetic energy or thermal energy.

24. The device according to any one of claims 18 to 23, characterized in that the powder active material that emits electrons is a material selected from the group consisting of a hydrogen-absorbing alloy of cadmium, iron, zinc and lead.

25. The device according to any one of claims 18-24, wherein the powdered active material that absorbs electrons is a material selected from the group consisting of nickel hydroxide, nickel dioxide and manganese dioxide.

26. The device according to any one of claims 18 to 25, wherein the electrolyte solution is a solution selected from the group consisting of potassium hydroxide solution, sodium hydroxide solution and dilute sulfuric acid.

27. An alkaline primary battery containing a cathode current collector, a cathode active material and an electrolyte solution, a separator that allows the passage of ions but impedes the passage of electrons, an anode active material and an electrolyte solution, and an anode current collector, which are installed in this order, as the anode active material using metal carbide, or a mixture of metal carbide and metal.

28. An alkaline secondary battery containing a cathode current collector, a cathode active material and an electrolyte solution, a separator that allows the passage of ions but prevents the passage of electrons, an anode active material and an electrolyte solution, and an anode current collector, which are installed in this order, and as an anode active material using metal carbide, or a mixture of metal carbide and metal.

29. The alkaline primary battery according to item 27, wherein the cathode active material and the anode active material are powder.

30. The alkaline secondary battery according to claim 28, wherein the cathode active material and the anode active material are powder.

31. The alkaline primary battery according to item 27 or 29, characterized in that the metal is iron, and the metal carbide is iron carbide.

32. The alkaline secondary battery according to claim 28 or 30, wherein the metal is iron and the metal carbide is iron carbide.

33. A method of locally distributed energy generation, in which a device for energy generation is used, comprising an engine selected from the group consisting of a gasoline engine, a diesel engine and a gas turbine to turn on an electric generator and generate energy, and a three-dimensional design battery that contains two containers connected by means of an element installed between them, which allows the passage of ions and prevents the passage of electrons, powder active material filling one of the containers it is suspended in an electrolyte solution for emitting electrons, and an active powder material filling another container and suspended in an electrolyte solution for absorbing electrons, while in two containers there are conductive current collectors in contact with powder active materials, as a battery for accumulating the generated energy, wherein the power generation device and the three-dimensional design battery are mounted on a vehicle selected from the group consisting of motorized about a two-wheeled vehicle, a motorized three-wheeled vehicle, a motorized four-wheeled vehicle and a ship that moves due to the engine and due to the energy of an electric motor driven by battery power, and connects a three-dimensional design battery installed in the vehicle to an inverter installed in a residential building or office, so that the energy generated in the vehicle’s electric generator is used in the load in the residential building at home or in the office, when the vehicle is not moving, using the specified vehicle as stationary equipment for generating energy for a residential building or office.

34. The method of locally distributed energy generation according to claim 33, wherein the device is used to generate energy using a battery of electrochemical generators instead of a device that uses an internal combustion engine to turn on an electric generator for energy generation.

35. The method of locally distributed energy generation according to claim 33 or 34, characterized in that at least the equipment for generating energy from solar energy or the equipment for generating energy from wind energy, a three-dimensional design battery, is installed in a residential building or in the office building, which contains two containers connected by means of an element installed between them, which allows the passage of ions and prevents the passage of electrons, an active powder material filling one of the containers and suspension embedded in an electrolyte solution for emitting electrons, and powdered active material filling another container and suspended in an electrolyte solution for absorbing electrons, while conductive current collectors in contact with powder active materials are placed in two containers, used as a stationary battery for accumulation of equipment energy, and a three-dimensional battery installed in a non-moving vehicle is connected to a stationary battery for tapping the cores of a stationary battery, and the energy from a stationary battery is converted into alternating current and its voltage is regulated by an inverter used in a load in a residential building or in an office building.

36. The method of locally distributed energy generation according to claim 35, characterized in that energy is generated that is generated at least either in solar energy generation equipment or in wind energy generation equipment to recharge the vehicle’s battery, which does not move.

37. The method of locally distributed energy production according to any one of paragraphs 33, 34 or 35, which serves high-temperature substances and / or low-temperature substances produced in a non-moving vehicle, in a residential building or office for the implementation of joint energy production.

38 The method of locally distributed energy generation according to any one of claims 33, 34, 35 or 37, characterized in that the silencer is installed externally on the vehicle to reduce engine exhaust sound when the engine is used to turn on an electric generator to supply energy to a residential or office building premises when the vehicle, including any one selected from the group consisting of a motorized two-wheeled vehicle, a motorized three-wheeled vehicle and a motorized four-wheeled vehicle nsportnogo means is not moved.

39. A locally distributed power generation device comprising a vehicle, including any one of the group consisting of a motorized two-wheeled vehicle, a motorized three-wheeled vehicle, and a motorized four-wheeled vehicle, and a ship that uses a device containing a motor selected from the group consisting of from a gasoline engine, diesel engine, gas turbine engine, to drive an electric generator to generate energy and an extra-battery containing two containers connected by an element installed between them that allows the passage of ions but prevents the passage of electrons, a powder active material filling one of the containers and suspended in an electrolyte solution to emit electrons, and a powder active material filling another container and suspended in an electrolyte solution for the absorption of electrons, while conductive current collectors in contact with active powders are installed in two containers materials, and containers serve as a battery for accumulating the generated energy, a device for generating energy and a three-dimensional design battery are installed in the vehicle, which is moved by the engine and due to the electric motor driven by battery power, an inverter installed in a residential building or office for supplying alternating current and energy of the regulated voltage to each load of a house or office, and a connector that connects the battery three-dimensional structures installed in a non-moving vehicle, with an inverter installed in a residential building or office space, while the energy generated by the vehicle’s electric generator is intended for use in the load of a residential building or office building.

40. The locally distributed energy generation device according to claim 39, characterized in that it uses the device to generate energy using a battery of electrochemical generators instead of a device in which a motor is used to drive an electric generator to generate energy.

41. The device of locally distributed energy generation according to any one of clauses 39 or 40, characterized in that at least the equipment for generating energy from solar energy or the equipment for generating energy from wind energy is installed in a residential building or in the office building, wherein a three-dimensional design battery containing two containers connected by an element installed between them, which allows the passage of ions and prevents the passage of electrons, a powdered active material filling one of the containers it is suspended in an electrolyte solution for emitting electrons, and powdered active material filling another container and suspended in an electrolyte solution for absorbing electrons, while conductive current collectors in contact with powder active materials are installed in two containers, and the containers are used as a stationary battery for accumulation of energy generated in the equipment, and the energy generated in the equipment is supplied to the load through an inverter connected to a stationary Atar, a battery of three-dimensional design, installed in unmovable vehicle, is connected to a stationary battery with a connector for supplying stationary battery energy generated in the power generator of the vehicle.

42. The locally distributed energy generation device according to paragraph 41, wherein the energy is supplied from a stationary battery, in which the energy generated by at least the energy generation equipment from solar energy or the energy generation equipment from wind energy is accumulated in the battery non-moving vehicle.

43. The device of locally distributed energy generation according to any one of paragraphs 39, 40 or 41, characterized in that the heat source of the vehicle is configured to communicate with a residential building or office through a pipeline for supplying high-temperature substances to a residential building or office or / and low-temperature substances produced in a non-moving vehicle to create a joint production system.