Redox flow battery

1 . A redox flow battery comprising: a tank configured to store an electrolyte; and a distribution mechanism to distribute the electrolyte to a battery cell; wherein the tank has a partition portion partitioning a space inside the tank into a first space and a second space, the distribution mechanism has a distribution passage through which the electrolyte is distributed between the first space and the second space via the battery cell, and the partition portion is composed of a flexible material. 2 . The redox flow battery according to claim 1 , wherein the partition portion has an outer region provided at an entire peripheral edge of the partition portion and an inner region surrounded by the outer region, a region of the outer region that comes into contact with the electrolyte is substantially liquid-tightly fixed to an inner surface of the tank, and the inner region allows change in volumes of spaces such that a volume of one of the first space and the second space increases and a volume of the other space decreases along with an increase or a decrease in an amount of the electrolyte in the first space and the second space. 3 . The redox flow battery according to claim 1 , wherein the distribution mechanism includes: a first supply passage to supply the electrolyte in the first space to the battery cell; a second supply passage to supply the electrolyte in the second space to the battery cell; one supply-side connection passage connecting downstream sides of the first supply passage and the second supply passage to the battery cell; a first discharge passage to discharge the electrolyte that has passed through the battery cell into the first space; a second discharge passage to discharge the electrolyte that has passed through the battery cell into the second space; one discharge-side connection passage connecting upstream sides of the first discharge passage and the second discharge passage to the battery cell; a supply-side switching valve that is provided at a location where the first supply passage, the second supply passage, and the supply-side connection passage are connected to each other, the supply-side switching valve being configured to switch between allowing a flow of the electrolyte from the first supply passage to the supply-side connection passage and allowing a flow of the electrolyte from the second supply passage to the supply-side connection passage; and a discharge-side switching valve that is provided at a location where the first discharge passage, the second discharge passage, and the discharge-side connection passage are connected to each other, the discharge-side switching valve being configured to switch between allowing a flow of the electrolyte from the discharge-side connection passage to the first discharge passage and allowing a flow of the electrolyte from the discharge-side connection passage to the second discharge passage. 4 . The redox flow battery according to claim 3 , further comprising: a liquid amount detector configured to detect at least one of the amount of the electrolyte in the first space and the amount of the electrolyte in the second space; and a valve controller configured to control operations of the supply-side switching valve and the discharge-side switching valve based on a result of detection performed by the liquid amount detector. 5 . The redox flow battery according to claim 3 , further comprising: a presence/absence detector configured to detect whether or not a power request was made by a load to which power is to be supplied from the redox flow battery; a calculation part configured to calculate a state of charge of the electrolyte in the first space and the state of charge of the electrolyte in the second space; and a valve controller configured to control operations of the supply-side switching valve and the discharge-side switching valve based on a result of detection performed by the presence/absence detector and a result of calculation performed by the calculation part. 6 . The redox flow battery according to claim 1 , wherein the partition portion has an outer region provided at an entire peripheral edge of the partition portion and an inner region surrounded by the outer region, the outer region is fixed to a peripheral edge of a top plate of the tank, and the partition portion is suspended from the top plate of the tank, and the first space and the second space are provided in an inward space and an outward space inside the tank.