Air core reactor for rolling stock

The invention claimed is: 1. An air core reactor for rolling stock, comprising: a coil having unit coils wound around a central axis that is horizontal, the unit coils being adjacent to each other with a space therebetween in a central axis direction that is a direction of the central axis; a pair of supporting frames sandwiching the coil therebetween and having main faces opposing each other in the central axis direction; first spacers disposed in (i) at least one of spaces between the unit coils adjacent to each other in the central axis direction and (ii) a space between each of the supporting frames and the coil, the first spacers being insulative and having projection parts that project outwardly from an outer peripheral face of the coil around the central axis; second spacers each disposed between the projection parts of the first spacers adjacent to each other in the central axis direction; bolts each traversing the pair of supporting frames, the first spacers, and the second spacers; and fastening members fastened at both ends of each of the bolts to sandwich the pair of supporting frames so that the pair of supporting frames, the first spacers, and the second spacers are fixed relative to the bolts, wherein a spacing distance between the adjacent first spacers is greater than a central-axis-direction thickness of the unit coil located between the adjacent first spacers, the central-axis-direction thickness of the unit coil being of when the coil is not energized. 2. The air core reactor according to claim 1 , wherein each of the second spacers abuts the adjacent first spacers that sandwich each of the second spacers, and a central-axis-direction thickness of the second spacer is greater than the central-axis-direction thickness of the unit coil located between the adjacent first spacers sandwiching the second spacer, the central-axis-direction thickness of the unit coil being of when the coil is energized. 3. The air core reactor according to claim 1 , further comprising: third spacers each disposed within the through hole formed in each of the first spacers, wherein each of the third spacers abuts the adjacent second spacers sandwiching the first spacer having the through hole in which the third spacer is disposed, each of the bolts traverses the pair of supporting frames, the first spacers, the second spacers, and the third spacers, the fastening members are fastened at both ends of each of the bolts to sandwich the pair of supporting frames so that the pair of supporting frames, the first spacers, the second spacers, and the third spacers are fixed relative to the bolts, and a central-axis-direction thickness of the third spacer is greater than or equal to a central-axis-direction thickness of the first spacer having the through hole in which the third spacer is disposed. 4. The air core reactor according to claim 2 , further comprising: third spacers each disposed within the through hole formed in each of the first spacers, wherein each of the third spacers abuts the adjacent second spacers sandwiching the first spacer having the through hole in which the third spacer is disposed, each of the bolts traverses the pair of supporting frames, the first spacers, the second spacers, and the third spacers, the fastening members are fastened at both ends of each of the bolts to sandwich the pair of supporting frames so that the pair of supporting frames, the first spacers, the second spacers, and the third spacers are fixed relative to the bolts, and a central-axis-direction thickness of the third spacer is greater than or equal to a central-axis-direction thickness of the first spacer having the through hole in which the third spacer is disposed. 5. The air core reactor according to claim 1 , wherein the first spacers are a plurality of pairs of first spacers extending in the vertical direction, each pair of first spacers opposing each other in a horizontal direction on opposite sides of the central axis, and both ends of each of the first spacers in the vertical direction form the projection parts. 6. The air core reactor according to claim 2 , wherein the first spacers are a plurality of pairs of first spacers extending in the vertical direction, each pair of first spacers opposing each other in a horizontal direction on opposite sides of the central axis, and both ends of each of the first spacers in the vertical direction form the projection parts. 7. The air core reactor according to claim 3 , wherein the first spacers are a plurality of pairs of first spacers extending in the vertical direction, each pair of first spacers opposing each other in a horizontal direction on opposite sides of the central axis, and both ends of each of the first spacers in the vertical direction form the projection parts. 8. The air core reactor according to claim 1 , wherein a space is defined between an outer peripheral face of each of the bolts and a wall surface of a through hole formed in each of the first spacers and traversed by each of the bolts. 9. The air core reactor according to claim 2 , wherein a space is defined between an outer peripheral face of each of the bolts and a wall surface of a through hole formed in each of the first spacers and traversed by each of the bolts. 10. The air core reactor according to claim 3 , wherein a space is defined between an outer peripheral face of each of the bolts and a wall surface of a through hole formed in each of the first spacers and traversed by each of the bolts. 11. The air core reactor according to claim 1 , further comprising: a supporting member abutting the outer peripheral face of the coil or an inner peripheral face of the coil around the central axis to suppress movement of the coil in the central axis direction, and supporting the coil in a vertical direction, the supporting member being insulative. 12. The air core reactor according to claim 2 , further comprising: a supporting member abutting the outer peripheral face of the coil or an inner peripheral face of the coil around the central axis to suppress movement of the coil in the central axis direction, and supporting the coil in a vertical direction, the supporting member being insulative. 13. The air core reactor according to claim 11 , wherein the second spacers disposed between the projection parts that are formed by vertically lower-side ends of the first spacers serve as the supporting member, and the second spacers are formed as insulating members, and abut the outer peripheral face of the coil and are fixed to the coil to support the coil in the vertical direction. 14. The air core reactor according to claim 12 , wherein the second spacers disposed between the projection parts that are formed by vertically lower-side ends of the first spacers serve as the supporting member, and the second spacers are formed as insulating members, and abut the outer peripheral face of the coil and are fixed to the coil to support the coil in the vertical direction. 15. The air core reactor according to claim 11 , wherein the supporting member is fixed at both ends thereof to the pair of supporting frames and abuts the inner peripheral face of the coil and is fixed to the coil to support the coil in the vertical direction. 16. The air core reactor according to claim 12 , wherein the supporting member is fixed at both ends thereof to the pair of supporting frames and abuts the inner peripheral face of the coil and is fixed to the coil to support the coil in the vertical direction. 17. The air core reactor according to claim 1 , wherein