Solid-gas reaction substance-filled reactor and method for manufacturing the same

What is claimed is: 1. A solid-gas reaction substance-filled reactor comprising: (1) a core part in which first to (n+1)-th heat medium heat-transfer tubes (n≥1) with heat medium flow paths for flowing a heat medium and frame-shaped first to n-th spacers with opening ends for introducing and discharging a gas are alternately stacked along a z-axis direction such that the heat medium flow paths and the opening ends are each oriented in almost the same direction, and first and second core division walls are each arranged at both ends as seen in the z-axis direction; a gas introduction/discharge part that is joined to the core part in such a manner as to communicate with the opening ends of the first to n-th spacers; and a heat medium introduction/discharge part that is joined to the core part in such a manner as to communicate with the heat medium flow paths, (2) the core part further includes a k-th filled body (1≤k≤n) that is inserted into a space surrounded by a k-th spacer (1≤k≤n), a k-th heat medium heat-transfer tube, and a (k+1)-th heat medium heat-transfer tube, the k-th filled body includes: a bag that is formed from metallic foil and is opened on the opening end side of the k-th spacer; and a solid-gas reaction substance filled in the bag, and (3) Brazing is applied at least between the k-th filled body (1≤k≤n) and the k-th heat medium heat-transfer tube and between the k-th filled body and the (k+1)-th heat medium heat-transfer tube. 2. The solid-gas reaction substance-filled reactor according to claim 1 , wherein the solid-gas reaction substance includes a metal hydride. 3. The solid-gas reaction substance-filled reactor according to claim 1 , wherein the gas introduction/discharge part has a filter to prevent scattering of the solid-gas reaction substance. 4. The solid-gas reaction substance-filled reactor according to claim 1 , wherein each of the first to (n+1)-th heat medium heat-transfer tubes includes a plurality of the heat medium flow paths that penetrates from one end to the other end of the heat medium heat-transfer tube. 5. The solid-gas reaction substance-filled reactor according to claim 4 , wherein the heat medium introduction/discharge part includes: a manifold that has an inlet and an outlet for the heat medium and is connected to the core part in such a manner as to communicate with first ends of the heat medium flow paths; and a header that is connected to the core part in such a manner as to communicate with second ends of the heat medium flow paths, the manifold distributes the heat medium supplied from the inlet to the first to (n+1)-th heat medium heat-transfer tubes, and supplies the distributed heat medium to some of the heat medium flow paths included in the k-th heat medium heat-transfer tube (1≤k≤n+1), and the header causes the heat medium discharged from some of the heat medium flow paths to turn around toward the remaining heat medium flow paths and discharges the same from the outlet. 6. The solid-gas reaction substance-filled reactor according to claim 4 , wherein the heat medium introduction/discharge part includes: a first manifold having an inlet for the heat medium and connected to the core part in such a manner as to communicate with first ends of the heat medium flow paths; and a second manifold having an outlet for the heat medium and connected to the core part in such a manner as to communicate with second ends of the heat medium flow paths and, the first manifold distributes the heat medium supplied from the inlet to the first to (n+1)-th heat medium heat-transfer tubes, and supplies the distributed heat medium to all the heat medium flow paths included in the first to (n+1)-th heat medium heat-transfer tubes in the same direction, and the second manifold discharges from the outlet the heat medium discharged from the heat medium flow paths. 7. The solid-gas reaction substance-filled reactor according to claim 4 , wherein the heat medium introduction/discharge part includes: a first manifold having an inlet for the heat medium and connected to the core part in such a manner as to communicate with first ends of the heat medium flow paths; and a second manifold having an outlet for the heat medium and connected to the core part in such a manner as to communicate with second ends of the heat medium flow paths and, each of the first manifold and the second manifold connects in series the heat medium flow paths included in the k-th heat medium heat-transfer tube and the heat medium flow paths included in the (k+1)-th heat medium heat-transfer tube such that: (a) the heat medium flows in the +x-axis direction in the heat medium flow paths included in the k-th heat medium heat-transfer tube, and (b) the heat medium flows in the −x-axis direction in the heat medium flow paths included in the (k+1)-th heat medium heat-transfer tube. 8. The solid-gas reaction substance-filled reactor according to claim 4 , wherein the first to (n+1)-th heat medium heat-transfer tubes have the heat medium flow paths arranged such that the flowing direction of the heat medium is almost the same as the flowing direction of a gas, the heat medium introduction/discharge part includes: a first manifold having an inlet for the heat medium and connected to the core part in such a manner as to communicate with first ends of the heat medium flow paths; and a second manifold having an outlet for the heat medium and connected to the core part in such a manner as to communicate with second ends of the heat medium flow paths, the first manifold distributes the heat medium supplied from the inlet to the first to (n+1)-th heat medium heat-transfer tubes and supplies the distributed heat medium to all the heat medium flow paths included in the first to (n+1)-th heat medium heat-transfer tubes in the same direction, and the second manifold discharges the heat medium from the heat medium flow paths from the outlet. 9. A method for manufacturing a solid-gas reaction substance-filled reactor comprising the following steps: (1) a first step of preparing first to n-th filled bodies (n≥1) in which a solid-gas reaction substance is filled into bag formed from metallic foil; (2) a second step of placing a first brazing material sheet (A), a first heat medium heat-transfer tube with heat medium flow paths, a first brazing material sheet (B), and a frame-shaped first spacer with an opening end in this order on a first core division wall, and inserting the first filled body into the first spacer; (3) when n≥2, a third step of alternately repeating: a step of placing a (k+1)-th brazing material sheet (A), a (k+1)-th heat medium heat-transfer tube with heat medium flow paths, a (k+1)-th brazing material sheet (B), and a frame-shaped (k+1)-th spacer with an opening end in this order on a k-th spacer and a k-th filled body (1≤k≤n−1) such that the heat medium flow paths are oriented in almost the same direction and the opening ends are oriented in almost the same direction; and a step of inserting the (k+1)-th filled body into the (k+1)-th spacer; (4) a fourth step of placing an (n+1)-th brazing material sheet (A), an (n+1)-th heat medium heat-transfer tube with heat medium flow paths, an (n+1)-th brazing material sheet (B), and a second core division wall in this order on an n-th spacer and the n-th filled body such that the heat medium flow paths are oriented in almost the same direction to obtain a stacked body; (5) a fifth step of melting the first to (n+1)-th brazing material sheets (A) and the first to (n+1)-th brazing material sheets (B) to braze between the members included in the stacked body to obtain a core part; and (6) a sixth step of joining a gas introduction/discharge part to the core part i