Superconducting flywheel power storage system demonstration machine has been completed.
Started commissioning of the world’s largest superconducting flywheel power storage system
Railway Technical Research Institute
Kubotech Co., Ltd.
Furukawa Electric Industry Co., Ltd.
Mirapro Co., Ltd.
Yamanashi Prefectural Enterprise Bureau
Now the world’s largest-class superconducting flywheel power storage system with a superconducting magnetic bearing was completed and test operation was started.
The flywheel power storage system is capable of storing electricity in the form of kinetic energy by rotating a flywheel, and converting the rotating power again to electricity, if necessary. Since this rechargeable battery does not deteriorate over time, it can be used for many purposes. For example, being combined with rather unstable power-generation systems such as photovoltaic or wind-power generation, it can help stabilize power supplies. It is also possible to apply this system to railways in order to prevent regenerative cancellation. For this system, RTRI developed a superconducting magnetic bearing composed of a high-temperature superconducting coil and high-temperature superconducting bulk. In this system, the flywheel is levitated by the superconducting magnetic bearing without contact. Therefore, the power loss is minimal although a large flywheel is used, and it is a very practical system which enables stable power generation over a long period.
The completed system is the world’s largest-class flywheel power storage system using a superconducting magnetic bearing. It has 300-kW output capability and 100-kWh storage capacity, and contains a CFRP (carbon-fiber-reinforced-plastic) flywheel. This flywheel is 2 m in diameter and weighs 4 tons, and is rotated with a superconducting magnetic bearing at a maximum speed of 6,000 RPM. This is the world’s first superconducting magnetic bearing which uses superconducting material both for its rotor and bearing, and is capable of supporting heavy weight, although it is a compact-sized system.
The details of this technical development will be presented at the 91st Cryogenic and Superconducting Engineering Technical Meeting scheduled on May 27, 2015. Grid-connection tests with a megawatt-class solar power plant will also be started this summer at Komekurayama in Yamanashi Prefecture.
This system has been developed jointly with Kuboteck Corporation, Furukawa Electric Co., Ltd., Mirapro Co., Ltd., and the Public Enterprise Bureau of Yamanashi Prefecture, in a project known as “the Technical Development for Safe, Low-Cost, Large-Capacity Battery System – the Development of the Next-Generation Flywheel Power Storage System” sponsored by the New Energy and Industrial Technology Development Organization (NEDO)
References:Details of the system
Characteristics
The larger and heavier the flywheel is, and the faster it rotates, the larger the amount of energy the power storage system can store. In this “superconducting flywheel power system”, the following technical developments have enabled a large-diameter, heavy-weight flywheel to rotate with higher speeds and less power loss.
1. Large-sized CFRP flywheel
For CFRP (carbon fiber-reinforced plastic) flywheels which have been developed so far, have a 1-meter diameter has been the upper limit due to restriction in strength and cost. For this system, however, higher strength and reliability were attained by a better method of weaving carbon fiber and 2-meter diameter flywheel was developed. This flywheel is made by stacking nine layers of CFRP rotors with a 2-meter outer diameter, 1.4-meter inner diameter and 10-centimeter thickness. With this method, flywheels of different storage capacities can be made by changing the number of layers.
2. Superconducting magnetic bearings
The superconducting magnetic bearing of this system uses a high-strength, high temperature superconducting magnet made of a second-generation high-temperature superconducting wire material containing yttrium. The rotating shaft also uses high-temperature superconducting bulk. We have succeeded in lifting the 4-ton flywheel without any contact by refrigerating the bearing to 50K, that is, -223℃, and creating a powerful magnetic field. This technique has made it possible to rotate the flywheel at a highspeed, with less energy loss. Furthermore, since this system operates at significantly higher temperatures than 20K or -253℃ of the previous superconducting coil, the refrigeration cost can be reduced.
Schedule for grid-connection tests
Basic performance of this system will be tested and adjusted in confirmation tests and moved to a megawatt-class solar power plant at Komekurayama in Yamanashi Prefecture. There it will be connected to the solar power system and the power grid of Tokyo Electric Power Company, and confirmation testing will be started to help stabilize fluctuating supply of renewable energy.
System configuration
Image of line-up of flywheel demonstration machine