Method of controlling switch circuit, storage status adjusting circuit, and storage battery pack

What is claimed is: 1. A method of controlling a switch circuit which includes n (n is a natural number greater than or equal to 3) switching units configured to respectively connect n storage batteries, which are connected in series, with n coils, wherein the n storage batteries have respective potential differences between opposite ends thereof, the method comprising the step of: controlling the switching units corresponding to k (k is a natural number wherein 1<k<n) storage batteries, which are secondary batteries other than a secondary battery having the largest potential difference among the potential differences of the n storage batteries, to connect the k storage batteries with respective k coils. 2. A method of controlling a switch circuit as claimed in claim 1 , wherein the switch circuit further includes: n changeover units configured to respectively change over between energy accumulation and energy release in the n coils, and the method further comprises the step of: releasing energy of the k coils, through the operations of k changeover units, when the k switching units are controlled to connect the k storage batteries with respective k coils. 3. A method of controlling a switch circuit as claimed in claim 2 , wherein the switching units respectively include: a first switching element configured to connect or disconnect a positive electrode of a storage battery with one end of a coil; a second switching element configured to connect or disconnect a negative electrode of the storage battery with the other end of the coil; wherein, the first switching element is controlled to switch off, based on the difference between an electric potential at the positive electrode of the storage battery and an electric potential at the one end of the coil, while the second switching element is controlled to switch off in synchronization with a timing at which a changeover unit is controlled to change over from energy release to energy accumulation. 4. A method of controlling a switch circuit as claimed in claim 3 , wherein the changeover units are controlled to let the coils release energy to the secondary batteries when potential differences between both ends of the respective coils reach a certain value. 5. A storage status adjusting circuit, comprising: n (n is a natural number greater than or equal to 3) switching units configured to respectively connect n storage batteries, which are connected in series, with n coils, wherein the n storage batteries have respective potential differences between opposite ends thereof; wherein the switching units corresponding to k (k is a natural number wherein 1<k<n) storage batteries, which are secondary batteries other than a secondary battery having the largest potential difference among the potential differences of the n storage batteries, are controlled to connect the k storage batteries with respective k coils. 6. A storage battery pack, comprising: n (n is a natural number greater than or equal to 3) coils; and n storage batteries, having respective potential differences between opposite ends thereof, which are connected in series, n switching units configured to respectively connect n storage batteries with n coils; wherein the switching units corresponding to k (k is a natural number wherein 1<k<n) storage batteries, which are secondary batteries other than a secondary battery having the largest potential difference among the potential differences of the n storage batteries, are controlled to connect the k storage batteries with respective k coils.