Flexible-printed-circuit joint structure, concentrator photovoltaic module, and flexible-printed-circuit joining method

1 . A flexible-printed-circuit joint structure, comprising: a junction box configured to connect an internal circuit of an apparatus and an external conductor to each other; a metal electrode being in the junction box and to be joined to the external conductor; and a flexible printed circuit in a strip shape, the flexible printed circuit forming the internal circuit and having an end portion to be joined to the metal electrode, wherein the metal electrode has a joint portion to be joined to the end portion in a superposed manner, and the joint portion in a free and lone state before being superposed on the end portion is ensured to have a gap greater than a thickness of the end portion, between the joint portion and a surface opposed to the joint portion, and has movability toward the opposed surface side when the joint portion is pressed. 2 . The flexible-printed-circuit joint structure according to claim 1 , wherein the joint portion is formed from a part of the metal electrode so as to have the gap, with a base portion except the part of the metal electrode assumed as the opposed surface. 3 . The flexible-printed-circuit joint structure according to claim 2 , wherein the joint portion has elasticity that allows the joint portion to come close to the opposed surface. 4 . The flexible-printed-circuit joint structure according to claim 1 , wherein a pair of the joint portions is provided in the metal electrode, a pair of the flexible printed circuits is present, and end portions of the pair of the flexible printed circuits are respectively joined to the pair of the joint portions. 5 . The flexible-printed-circuit joint structure according to claim 4 , wherein the junction box has a protrusion formed therein, the metal electrode is engaged with the protrusion by means of a recess formed in a center portion of the metal electrode, and the end portions of the pair of the flexible printed circuits face the protrusion from opposite sides of the protrusion. 6 . The flexible-printed-circuit joint structure according to claim 5 , wherein each joint portion in a free and lone state before being superposed on the end portion corresponding thereto is ensured to have the gap between the joint portion and the opposed surface, due to the engagement with the protrusion. 7 . The flexible-printed-circuit joint structure according to claim 1 , wherein the junction box is provided on a bottom surface of the apparatus and is formed so as to be recessed relative to the bottom surface. 8 . A concentrator photovoltaic module comprising: a concentrating portion in which condenser lenses each converging sunlight are arranged in a matrix shape; a housing configured to support the concentrating portion; a flexible printed circuit arranged on a bottom surface of the housing; power generating elements arranged on the flexible printed circuit so as to correspond to light-concentrating positions of the respective condenser lenses; a junction box formed in a part of the bottom surface of the housing so as to be recessed relative to the bottom surface, the junction box having connected thereto an external conductor for collecting outputs of the power generating elements and for providing the collected outputs to outside; a metal electrode being in the junction box and to be joined to the external conductor; and a flexible printed circuit in a strip shape, the flexible printed circuit forming an internal circuit and having an end portion to be joined to the metal electrode, wherein the metal electrode has a joint portion to be joined to the end portion in a superposed manner, and the joint portion in a free and lone state before being superposed on the end portion is ensured to have a gap greater than a thickness of the end portion, between the joint portion and a surface opposed to the joint portion, and has movability toward the opposed surface side when the joint portion is pressed. 9 . The concentrator photovoltaic module according to claim 8 , wherein the flexible printed circuit is arranged so as to seamlessly continue on the bottom surface. 10 . A flexible-printed-circuit joining method in which, in a junction box for connecting an internal circuit of an apparatus and an external conductor to each other, a metal electrode to be joined to the external conductor is connected to an end portion of a strip-shaped flexible printed circuit forming the internal circuit, the method comprising: establishing a state in which a joint portion, of the metal electrode, to be joined to the end portion in a superposed manner is ensured to have a predetermined gap in a free and lone state of the joint portion, between the joint portion and a surface opposed to the joint portion, and has movability toward the opposed surface side when the joint portion is pressed; inserting into the gap the end portion having a smaller thickness than a dimension of the gap; and joining the joint portion and the end portion to each other by performing local heating thereon in a state where the joint portion and the end portion are closely attached to each other with a welder electrode pressed against the joint portion.