Battery system and method of determining polarization of secondary battery

The invention claimed is: 1. A battery system comprising: a chargeable and dischargeable battery unit; and a controller estimating a polarization state of the battery unit, wherein the controller is configured to: calculate a concentration distribution in an active material of the battery unit by using a diffusion equation, and calculate a first polarization elimination time taken for the concentration distribution in the active material to fall within an allowable range assuming that the charge and the discharge of the battery unit is not performed, calculate a concentration distribution in an electrolyte of the battery unit by using a diffusion equation, and calculate a second polarization elimination time taken for the concentration distribution in the electrolyte to fall within an allowable range assuming that the charge and the discharge of the battery unit is not performed, measure a time for which the charge and the discharge of the battery unit is not performed try using a timer, and determine that polarization of the battery unit is eliminated when the time for which the charge and the discharge of the battery unit is not performed is longer than a longer polarization elimination time of the first polarization elimination time and the second polarization elimination time. 2. The battery system according to claim 1 , wherein the controller is configured to: obtain a voltage of the battery unit by using a voltage sensor when the time for which the charge and the discharge of the battery unit is not performed is longer than the longer polarization elimination time, and use information representing a relationship between charge states and open circuit voltages of the battery unit to specify the charge state associated with the obtained voltage. 3. The battery system according to claim 1 , wherein the controller is configured to use a voltage drop characteristic of the battery unit observed while the charge and the discharge of the battery unit is not performed to calculate an open circuit voltage of the battery unit when the time for which the charge and the discharge of the battery unit is not performed is shorter than the longer polarization elimination time. 4. The battery system according to claim 1 , wherein the controller is configured to: calculate a maximum concentration at which a largest difference is present between an average concentration calculated from the concentration distribution in the active material and a concentration in the active material, and use a relationship between the maximum concentration and the first polarization elimination time to specify the first polarization elimination time associated with the calculated maximum concentration. 5. The battery system according to claim 1 , wherein the controller is configured to use a relationship between the concentration distribution in the electrolyte and the second polarization elimination time to specify the second polarization elimination time associated with the calculated concentration distribution in the electrolyte. 6. The battery system according to claim 1 , wherein the controller is configured to set a concentration at each of the center and an interface of the active material as a boundary condition and to use the diffusion equation to calculate the concentration distribution in the active material. 7. The battery system according to claim 1 , wherein the battery unit is a unit cell. 8. The battery system according to claim 1 , wherein the battery unit has a plurality of unit cells connected electrically. 9. The battery system according to claim 1 , wherein the battery unit is configured to output an electric energy which is to be converted into a kinetic energy for running a vehicle. 10. A determination method for determining a polarization state of a chargeable and dischargeable battery unit, comprising: calculating a concentration distribution in an active material of the battery unit by using a diffusion equation, and calculating a first polarization elimination time taken for the concentration distribution in the active material to fall within an allowable range assuming that the charge and the discharge of the battery unit is not performed, calculating a concentration distribution in an electrolyte of the battery unit by using a diffusion equation, and calculating a second polarization elimination time taken for the concentration distribution in the electrolyte to fall within an allowable range assuming that the charge and the discharge of the battery unit is not performed, measuring a time for which the charge and the discharge of the battery unit is not performed by using a timer, and determining that polarization of the battery unit is eliminated when the time for which the charge and the discharge of the battery unit is not performed is longer than a longer polarization elimination time of the first polarization elimination time and the second polarization elimination time.