Battery unit

What is claimed is: 1. A battery unit comprising: a battery module including a battery cell; a battery heat flow detector configured to detect a heat flow of the battery cell; a storage configured to store heat flow HF vs. state of charge SOC initial characteristics of the battery cell; and a battery state estimator configured to estimate a state of health SOH of the battery cell, wherein the battery state estimator measures, during charge of the battery cell, HF vs. SOC present characteristics of the battery cell, based on the heat flow HF of the battery cell detected by the battery heat flow detector, and estimates a first state of health SOH(R) of the battery cell, from a ratio between a length mAh of a line segment between peaks of differential characteristics of the measured HF vs. SOC present characteristics and a length mAh of a line segment between peaks of differential characteristics of the HF vs. SOC initial characteristics stored in the storage. 2. The battery unit according to claim 1 , further comprising: a voltage detector configured to detect a closed circuit voltage of the battery cell; and a current detector configured to detect a current of the battery cell, wherein the storage further stores enthalpy potential UH vs. SOC initial characteristics of the battery cell, an enthalpy potential UH being calculated according to a formula that is based on a closed circuit voltage CCV, a heat flow HF, and a current I, and is written as UH=CCV−HF/I; and wherein the battery state estimator further measures, during charge of the battery cell, UH vs. SOC present characteristics of the battery cell, based on the heat flow HF, the closed circuit voltage CCV, and the current I of the battery cell that are detected by the battery heat flow detector, the voltage detector, and the current detector, respectively, calculates enthalpy potential difference ΔUH vs. SOC characteristics by subtracting the UH vs. SOC initial characteristics stored in the storage from the measured UH vs. SOC present characteristics, estimates a second state of health SOH(I) of the battery cell, from a magnitude of a peak of differential characteristics of the calculated ΔUH vs. SOC characteristics, and estimates an increase in resistance loss R caused by degradation of the battery cell, from a difference between the first state of health SOH(R) and the second state of health SOH(I). 3. The battery unit according to claim 2 , wherein the storage stores in advance differential characteristics of the enthalpy potential difference ΔUH vs. SOC characteristics in a predetermined second state of health SOH(I) of the battery cell, and wherein the battery state estimator assumes, from a magnitude of a peak of the differential characteristics of the ΔUH vs. SOC characteristics in the predetermined second state of health SOH(I) stored in the storage, that there is a proportional relationship between the second state of health SOH(I) and the magnitude of the peak, and estimates, based on the proportional relationship, the second state of health SOH(I) of the battery cell, from the magnitude of the peak of the differential characteristics of the calculated ΔUH vs. SOC characteristics. 4. The battery unit according to claim 2 , further comprising: a reference heat flow detector configured to detect, as a reference heat flow, a heat flow of the battery unit, wherein the battery state estimator subtracts the reference heat flow detected by the reference heat flow detector from the heat flow detected by the battery heat flow detector to thereby calculate a heat flow excluding effects of the heat flow in the battery unit, and uses the calculated heat flow as the heat flow of the battery cell. 5. The battery unit according to claim 1 , further comprising: a reference heat flow detector configured to detect, as a reference heat flow, a heat flow of the battery unit, wherein the battery state estimator subtracts the reference heat flow detected by the reference heat flow detector from the heat flow detected by the battery heat flow detector to thereby calculate a heat flow excluding effects of the heat flow in the battery unit, and uses the calculated heat flow as the heat flow of the battery cell. 6. A battery unit comprising: a battery module including a battery cell; a battery heat flow detector configured to detect a heat flow of the battery cell; a voltage detector configured to detect a closed circuit voltage of the battery cell; a current detector configured to detect a current of the battery cell; a storage configured to store enthalpy potential UH vs. state of charge SOC initial characteristics of the battery cell, an enthalpy potential UH being calculated according to a formula that is based on a closed circuit voltage CCV, a heat flow HF, and a current I, and is written as UH=CCV−HF/I; and a battery state estimator configured to estimate a state of health SOH of the battery cell, wherein the battery state estimator measures, during charge of the battery cell, UH vs. SOC present characteristics of the battery cell, based on the heat flow HF, the closed circuit voltage CCV, and the current I of the battery cell that are detected by the battery heat flow detector, the voltage detector, and the current detector, respectively, and estimates a second state of health SOH(I) of the battery cell, from a ratio between a length mAh of a line segment between peaks of differential characteristics of the measured UH vs. SOC present characteristics and a length mAh of a line segment between peaks of differential characteristics of the UH vs. SOC initial characteristics stored in the storage. 7. The battery unit according to claim 6 , further comprising: a reference heat flow detector configured to detect, as a reference heat flow, a heat flow of the battery unit, wherein the battery state estimator subtracts the reference heat flow detected by the reference heat flow detector from the heat flow detected by the battery heat flow detector to thereby calculate a heat flow excluding effects of the heat flow in the battery unit, and uses the calculated heat flow as the heat flow of the battery cell.