Nickel-hydrogen storage battery

The invention claimed is: 1. A nickel-hydrogen storage battery comprising a positive electrode, a negative electrode using an AB5 based hydrogen-absorbing alloy, and a separator arranged between the positive electrode and the negative electrode, wherein the AB 5 based hydrogen-absorbing alloy includes an A element, which is a constituent element of a misch metal, and a B element, the B element includes nickel and cobalt, a ratio of an amount of substance of the B element to an amount of substance of the A element is 5.2 or more and 5.4 or less, a ratio of an amount of substance of cobalt to the amount of substance of the A element is 0.15 or more and 0.4 or less, and a liquid retention volume (V 1 ), which is a volume of an electrolytic solution retained in the separator, a true volume (V 2 ), which is a volume of the separator in the case where no void exists in the separator, a theoretical capacity of the negative electrode (C 1 ), and a theoretical capacity of the positive electrode (C 2 ) satisfy the expression (1). 2.0≦ V 1 /V 2× C 1 /C 2≦3.1  (1) 2. The nickel-hydrogen storage battery according to claim 1 , wherein the ratio of the amount of substance of the B element to the amount of substance of the A element is 5.25 or more and 5.4 or less, the ratio of the amount of substance of cobalt to the amount of substance of the A element is 0.15 or more and 0.25 or less, and a ratio of a half-width of a peak of a (002) plane to a half-width of a peak of a (200) plane in X-ray diffraction is 1.3 or more and less than 1.7. 3. The nickel-hydrogen storage battery according to claim 1 , satisfying the expression (1′). 2.2≦ V 1/ V 2× C 1/ C 2≦2.8  (1′) 4. The nickel-hydrogen storage battery according to claim 1 , wherein a capacity ratio (C 1 /C 2 ), which is a ratio of the theoretical capacity of the negative electrode (C 1 ) to the theoretical capacity of the positive electrode (C 2 ), satisfy the expression (2). 1.2≦ C 1/ C 2≦1.35  (2) 5. A nickel-hydrogen storage battery comprising a positive electrode, a negative electrode using an AB5 based hydrogen-absorbing alloy, and a separator arranged between the positive electrode and the negative electrode, wherein the AB 5 based hydrogen-absorbing alloy includes an A element, which is a constituent element of a misch metal, and a B element, the B element includes nickel and cobalt, a ratio of an amount of substance of the B element to an amount of substance of the A element is 5.25 or more and 5.4 or less, a ratio of an amount of substance of cobalt to the amount of substance of the A element is 0.05 or more and 0.15 or less, a ratio of a half-width of a peak of a (002) plane to a half-width of a peak of a (200) plane in X-ray diffraction is 1.1 or more and less than 1.3, and a liquid retention volume (V 1 ), which is a volume of an electrolytic solution retained in the separator, a true volume (V 2 ), which is a volume of the separator in the case where no void exists in the separator, a theoretical capacity of the negative electrode (C 1 ), and a theoretical capacity of the positive electrode (C 2 ) satisfy the expression (1). 2.0≦ V 1/ V 2× C 1/ C 2≦3.1  (1) 6. A nickel-hydrogen storage battery comprising a positive electrode, a negative electrode using an AB5 based hydrogen-absorbing alloy, and a separator arranged between the positive electrode and the negative electrode, wherein the AB 5 based hydrogen-absorbing alloy includes an A element being a constituent element of a misch metal, and a B element, the B element includes nickel and cobalt, a ratio of an amount of substance of the B element to an amount of substance of the A element is 5.30 or more and 5.4 or less, a ratio of an amount of substance of cobalt to the amount of substance of the A element is 0.05 or more and 0.15 or less, a ratio of a half-width of a peak of a (002) plane to a half-width of a peak of a (200) plane in X-ray diffraction is 1.1 or more and less than 1.9, and a liquid retention volume (V 1 ), which is a volume of an electrolytic solution retained in the separator, a true volume (V 2 ), which is a volume of the separator in the case where no void exists in the separator, a theoretical capacity of the negative electrode (C 1 ), and a theoretical capacity of the positive electrode (C 2 ) satisfy the expression (1). 2.0≦ V 1/ V 2× C 1/ C 2≦3.1  (1)