Estimation device, estimation method, and computer program

The invention claimed is: 1. An estimation device comprising: a derivation unit configured to derive a derivation history based on a current, a voltage of a lead-acid battery and a temperature of the lead-acid battery acquired at a point of time of an estimation; a specifying unit configured to specify at least one physical quantity out of a first physical quantity of an amount of a positive active material, a second physical quantity of a specific surface area of a positive electrode material, a third physical quantity of bulk density of the positive electrode material, a fourth physical quantity of positive active material particles in a cluster size, a fifth physical quantity of a cumulative amount of lead sulfate of a negative electrode material, a sixth physical quantity of a specific surface area of the negative electrode material, a seventh physical quantity of a corrosion amount of a positive electrode grid, an eighth physical quantity of resistivity of a positive electrode plate, and a ninth physical quantity of resistivity of a negative electrode plate, based on the derived derivation history and at least one relationship selected from a group consisting of: a first relationship between a first history based on a preliminary obtained current, a preliminary obtained voltage of the lead-acid battery or a different lead-acid battery and a preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the first physical quantity; a second relationship between a second history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the second physical quantity; a third relationship between a third history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the third physical quantity; a fourth relationship between a fourth history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the fourth physical quantity; a fifth relationship between a fifth history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the fifth physical quantity; a sixth relationship between a sixth history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the sixth physical quantity; a seventh relationship between a seventh history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the seventh physical quantity; an eighth relationship between an eighth history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the eighth physical quantity; and a ninth relationship between a ninth history based on the preliminary obtained current, the preliminary obtained voltage of the lead-acid battery or the different lead-acid battery and the preliminary obtained temperature of the lead-acid battery or the different lead-acid battery and the ninth physical quantity, and an estimation unit configured to estimate a degree of deterioration of the lead-acid battery based on the at least one specified physical quantity. 2. The estimation device according to claim 1 , wherein the specifying unit is configured to specify the at least one physical quantity out of the first physical quantity to the ninth physical quantity based on the relationship between the history corresponding to a position of the plate in a height direction and the physical quantity at the position. 3. The estimation device according to claim 1 , wherein the derivation history includes: an effective discharge capacity obtained by correcting a discharge capacity by a coefficient based on a temperature; an effective charge capacity obtained by correcting a charge capacity by a coefficient based on a temperature; or a temperature cumulative value obtained by multiplying a temperature by a predetermined coefficient. 4. The estimation device according to claim 1 , wherein the specifying unit is configured to specify at least one physical quantity by inputting the derived derivation history into a first learning model, the first learning model is configured to output at least one physical quantity out of the first physical quantity, the second physical quantity, the third physical quantity, the fourth physical quantity, the fifth physical quantity, the sixth physical quantity, the seventh physical quantity, the eighth physical quantity, and the ninth physical quantity, when a derivation history based on a current, a voltage of a lead-acid battery and a temperature of the lead-acid battery is inputted to the first learning model. 5. The estimation device according to claim 1 , wherein the estimation unit is configured to estimate a degree of deterioration by inputting the at least one specified physical quantity to a second learning model, the second learning model is configured to output a degree of deterioration of a lead-acid battery when at least one physical quantity out of the first physical quantity, the second physical quantity, the third physical quantity, the fourth physical quantity, the fifth physical quantity, the sixth physical quantity, the seventh physical quantity, the eighth physical quantity, and the ninth physical quantity is inputted to the second learning model. 6. The estimation device according to claim 1 , wherein the specifying unit is configured to specify the at least one physical quantity based on the derivation history and design information on the lead-acid battery. 7. The estimation device according to claim 6 , wherein the design information is at least one selected from a group consisting of; a number of plates; an amount of the positive active material; a mass of the positive electrode grid; a thickness of the positive electrode grid; a design of the positive electrode grid; density of the positive electrode material; composition of the positive active material; an amount and a kind of an additive in the positive active material; a composition of a positive electrode alloy; a presence or non-presence, a thickness, a material and gas permeability of a non-woven fabric that is brought into contact with the positive electrode plate; an amount of negative active material; an amount and a kind of carbon in the negative electrode material; an amount and a kind of an additive in the negative electrode material; a specific surface area of the negative electrode material; a kind and concentration of an additive in an electrolyte solution; and a specific gravity and an amount of the electrolyte solution. 8. The estimation device according to claim 1 , wherein the estimation unit is configured to estimate the degree of deterioration based on the at least