Secondary battery and secondary battery control method

The invention claimed is: 1. A secondary battery comprising: a power generation element having at least one unit cell layer including a positive electrode, a separator and a negative electrode stacked in that order; an electroconductive member disposed on at least one outward side of the power generation element in a direction in which the unit cell layer is stacked with an electrical insulation member interposed between the electroconductive member and the power generation element; an external short circuit electrically connecting the electroconductive member to an electrode of an opposite polarity to that of an electrode on an outermost layer of the power generation element where the electroconductive member is disposed; a current detector arranged to detect whether or not current is flowing to the external short circuit; and an external discharge safety circuit provided with an opening-closing device configured to electrically insulate a path between the positive electrode of the power generation element and the negative electrode of the power generation element when the current sensor has not detected current, and short-circuits the path between the positive electrode of the power generation element and the negative electrode of the power generation element outside the power generation element when the current sensor has detected current. 2. The secondary battery according to claim 1 , wherein the current sensor and the opening-closing device include a relay having a coil and a switch; the coil is interposed partway along the external short circuit, and the switch is placed so as to open and close the path between the positive electrode of the power generation element and the negative electrode of the power generation element; and the switch is actuated by current flowing to the coil, short-circuiting the path between the positive electrode of the power generation element and the negative electrode of the power generation element. 3. The secondary battery according to claim 1 , wherein the current sensor is a current sensor that detects a current flow to the external short circuit; and the external discharge safety circuit has a control unit that receives a signal indicating that the current sensor has detected the current flow, and actuates the opening-closing device to short-circuit the path between the positive electrode of the power generation element and the negative electrode of the power generation element. 4. The secondary battery according to claim 1 , wherein the current sensor is a voltage sensor that detects that a current flow to the external short circuit according to a voltage drop in a resistor interposed partway along the external short circuit; and the external discharge safety circuit has a control unit that receives a signal indicating that the voltage sensor has detected the current flow, and actuates the opening-closing device to short-circuit the path between the positive electrode of the power generation element and the negative electrode of the power generation element. 5. The secondary battery according to claim 1 , wherein the electrical insulation member includes a first electrical insulation member and a second electrical insulation member, the electroconductive member includes a first electroconductive member disposed on a first outward side of the power generation element in the direction in which the unit cell layer is stacked with the first electrical insulation member interposed between the first electroconductive member and the power generation element, and a second electroconductive member disposed on a second outward side of the power generation element in the direction in which the unit cell layer is stacked with the second electrical insulation member interposed between the second electroconductive member and the power generation element; the external short circuit includes a first external short circuit that electrically connects the first electroconductive member and the electrode having the opposite polarity to that of the electrode in the outermost layer where the first electroconductive member is disposed, and a second external short circuit that electrically connects the second electroconductive member and the electrode having the opposite polarity to that of the electrode in the outermost layer where the second electroconductive member is disposed; and the external discharge safety circuit actuates the opening-closing device to short-circuit the path between the positive electrode of the power generation element and the negative electrode of the power generation element when the current sensor has detected current flow to at least either one of the first external short circuit and the second external short circuit. 6. A method for controlling the secondary battery according to claim 1 , method a secondary battery comprising: detecting current flowing to the external short circuit, and electrically short-circuiting a path between the positive electrode of the power generation element and the negative electrode of the power generation element outside the power generation element. 7. The method according to claim 6 , wherein the detecting of the current flow to the external short circuit, and the electrically short-circuiting of the path between the positive electrode of the power generation element and the negative electrode of the power generation element is performed by setting to ON a switch of a relay provided between the positive electrode of the power generation element and the negative electrode of the power generation element outside of the power generation element. 8. The method for controlling a secondary battery according to claim 6 , wherein the electrical insulation member includes a first electrical insulation member and a second electrical insulation member, the electroconductive member includes a first electroconductive member disposed on a first outward side of the power generation element in the direction in which the unit cell layer is stacked with the first electrical insulation member interposed between the first electroconductive member and the power generation element, and a second electroconductive member disposed on a second outward side of the power generation element in the direction in which the unit cell layer is stacked with the second electrical insulation member interposed between the second electroconductive member and the power generation element; the external short circuit includes a first external short circuit that electrically connects the first electroconductive member and the electrode having the opposite polarity to that of the electrode in the outermost layer where the first electroconductive member is disposed, and a second external short circuit that electrically connects the second electroconductive member and the electrode having the opposite polarity to that of the electrode in the outermost layer where the second electroconductive member is disposed; and the external discharge safety circuit actuates the opening-closing device to short-circuit the path between the positive electrode of the power generation element and the negative electrode of the power generation element when the current sensor has detected current flow to at least either one of the first external short circuit and the second external short circuit.