Power storage apparatus and method of operating power storage apparatus

The invention claimed is: 1. A power storage apparatus comprising: a battery that includes a container, an electric cell of a sodium-sulfur battery, and a charging/discharging path inside the battery, said container including an outer wall and a heat transfer wall, an electric cell chamber and an air chamber being formed inside said container, said heat transfer wall dividing said electric cell chamber and said air chamber, and said electric cell and said charging/discharging path inside the battery being housed in said electric cell chamber; a charging/discharging path outside the battery that is electrically connected to said charging/discharging path inside the battery; a sealed container, which is a separate container from the container that houses said battery and said charging/discharging path outside the battery, a battery chamber and an accessory chamber being formed inside said sealed container, and said battery being housed in said battery chamber, wherein said sealed container includes a partition wall that divides said battery chamber and said accessory chamber, hinders the circulation of air between said battery chamber and said accessory chamber, and suppresses heat transfer from said battery chamber to the accessory chamber; an intake path formation that is formed with an intake path which starts from outside of said sealed container and leads to said air chamber; an exhaust path formation that is formed with an exhaust path which starts from said air chamber and leads to outside of said sealed container; a generation mechanism that generates an air flow which sequentially flows through said intake path, said air chamber, and said exhaust path; a determination unit that determines whether or not cooling of said electric cell chamber is required; a generation control unit that controls said generation mechanism such that said air flow is generated in a case where said determination unit determines that the cooling of said electric cell chamber is required, and said air flow is not generated in a case where said determination unit determines that the cooling of said electric cell chamber is not required; and an accessory that is housed in said accessory chamber. 2. The power storage apparatus according to claim 1 , wherein said battery further includes a first temperature sensor that is housed in said electric cell chamber, and said determination unit determines that the cooling of said electric cell chamber is required, in a case where rising of a temperature measured by said first temperature sensor is equal to or greater than a reference. 3. The power storage apparatus according to claim 2 , further comprising: a second temperature sensor that is arranged outside said sealed container; and a flow rate control unit that controls said generation mechanism such that a flow rate of said air flow is increased as a temperature measured by said second temperature sensor rises. 4. The power storage apparatus according to claim 1 , further comprising: a heat insulator external to said air chamber with said outer wall interposed therebetween. 5. The power storage apparatus according to claim 1 , wherein said exhaust path does not pass through said accessory chamber. 6. The power storage apparatus according to claim 1 , wherein said battery includes two or more electric cells including said electric cell, wherein said two or more electric cells are housed in said electric cell chamber and are arranged in a direction parallel to said air chamber. 7. A method of operating a power storage apparatus comprising the steps of: (a) preparing a power storage apparatus including a battery, a charging/discharging path outside the battery, a sealed container, an intake path formation, an exhaust path formation, a generation mechanism and an accessory, said battery including a container, an electric cell of a sodium-sulfur battery, and a charging/discharging path inside the battery, said container including an outer wall and a heat transfer wall, an electric cell chamber and an air chamber being formed inside said container, said heat transfer wall dividing said electric cell chamber and said air chamber, and said electric cell and said charging/discharging path inside the battery being housed in said electric cell chamber, said charging/discharging path outside the battery and said charging/discharging path inside the battery being electrically connected to each other; said sealed container, which is a separate container from the container housing said battery and said charging/discharging path outside the battery; a battery chamber and an accessory chamber being formed inside said sealed container, said battery being housed in said battery chamber, and said accessory being housed in said accessory chamber, an intake path which starts from outside of said sealed container and leads to said air chamber being formed in said intake path formation; an exhaust path which starts from said air chamber and leads to outside of said sealed container being formed in said exhaust path formation; and said generation mechanism generating an air flow which sequentially flows through said intake path, said air chamber, and said exhaust path, wherein said sealed container includes a partition wall that divides said battery chamber and said accessory chamber, hinders the circulation of air between said battery chamber and said accessory chamber, and suppresses heat transfer from said battery chamber to the accessory chamber; (b) determining whether or not cooling of said electric cell chamber is required; and (c) controlling said generation mechanism such that said air flow is generated in a case where it is determined that the cooling of said electric cell chamber is required, and said air flow is not generated in a case where it is determined that the cooling of said electric cell chamber is not required.