Tensioner

The invention claimed is: 1. A tensioner comprising: a movable section configured to receive a load from an entrained transmission body through a tension member; a fixed section configured to support the movable section so as to be capable of being displaced; a flat spiral spring biasing the movable section so as to resist the tension member, the flat spiral spring unwinding in a state in which there is a small inter-plate friction force in a case in which there is a large biasing force applied to the tension member to counter the load acting from the tension member, and winding-up in a state in which there is a large inter-plate friction force in a case in which there is a small biasing force applied to the tension member to counter the load acting from the tension member; and a wind-up limiting section configured to limit wind-up of the flat spiral spring, wherein the wind-up limiting section includes a resistance force imparting section that is disposed inside an inner circumferential face of the flat spiral spring and configured to apply a biasing force against a decreased diameter of the flat spiral spring. 2. The tensioner of claim 1 , wherein the wind-up limiting section includes a displacement limiting section configured to permit displacement of the movable section toward the tension member with respect to the fixed section, and to limit displacement of the movable section toward an opposite side from the tension member with respect to the fixed section. 3. The tensioner of claim 1 , wherein: the resistance force imparting section is a back-up spring configured from plate-shaped spring material; and the back-up spring includes: a ring-shaped portion formed in an incomplete ring shape and having an outer circumferential face in contact with an inner circumferential face of the flat spiral spring, and an anchor portion extending from a one-end portion of the ring-shaped portion and anchored to the fixed section. 4. The tensioner of claim 3 , further comprising: a radial-contraction restriction member supported so as to be capable of rotating with respect to the fixed section about an axis running along a coil axis direction of the flat spiral spring, and engaged with another-end portion of the ring-shaped portion; and a rotation limiting section configured to permit the radial-contraction restriction member to rotate in one direction about the axis with respect to the fixed section interlocked to radial enlargement of the ring-shaped portion, and to limit the radial-contraction restriction member from rotating in another direction about the axis with respect to the fixed section interlocked to radial contraction of the ring-shaped portion. 5. The tensioner of claim 3 , further comprising: a first pin member fixed to the fixed section and having the anchor portion anchored to the first pin member; a second pin member disposed adjacently with respect to the first pin member in an extension direction of the ring-shaped portion from the anchor portion, the second pin member being fixed to the fixed section and engaged with an inner circumferential face of the ring-shaped portion; and a plate member fixed to the first pin member and the second pin member and limiting displacement of the flat spiral spring and the back-up spring in a coil axis direction of the flat spiral spring. 6. The tensioner of claim 3 , wherein the fixed section includes an inner circumferential support portion configured to engage with an inner circumferential face of the ring-shaped portion and to support the ring-shaped portion. 7. The tensioner of claim 3 , wherein the ring-shaped portion has a cross-sectional area that changes in a circumferential direction. 8. The tensioner of claim 3 , wherein the flat spiral spring has a curved cross-section, as viewed along a circumferential direction, that is convex on toward an opposite side from the ring-shaped portion. 9. The tensioner of claim 3 , wherein the outer circumferential face of the ring-shaped portion is, as viewed along a circumferential direction of the ring-shaped portion, formed in a convex shape that is convex toward the flat spiral spring. 10. The tensioner of claim 3 , wherein a plurality of indentations and projections are formed on an outer circumferential face and an inner circumferential face of a plate spring material configuring the flat spiral spring. 11. The tensioner of claim 3 , wherein: the movable section is supported by the fixed section so as to be capable of sliding in a reciprocating direction orthogonal to a coil axis direction of the flat spiral spring; the flat spiral spring is disposed adjacently with respect to the movable section in a spring-adjacency direction orthogonal to both the coil axis direction and the reciprocating direction, an outer-end portion of the flat spiral spring being anchored to the movable section, and an inner-end portion of the flat spiral spring being anchored to the fixed section; taking a rotation direction in which the flat spiral spring is wound-up as a wind-up direction and a rotation direction in which the flat spiral spring unwinds as an unwind direction, the ring-shaped portion extends from the anchor portion in the wind-up direction; and as viewed along the coil axis direction, the one-end portion of the ring-shaped portion is disposed in a range from a position at 0 degrees about a center of the ring-shaped portion to a position at 90 degrees in the unwind direction with respect to a virtual straight line extending in the spring-adjacency direction from the center of the ring-shaped portion toward the movable section. 12. The tensioner of claim 3 , wherein the ring-shaped portion is formed by the plate-shaped spring material being wound for at least 1.0 full turn. 13. The tensioner of claim 1 , wherein the resistance force imparting section includes: a plurality of press-contact members arrayed along a circumferential direction of the flat spiral spring; and a biasing portion configured to bias the plurality of press-contact members toward a radial direction outer side of the flat spiral spring so as to press-contact an inner circumferential face of the flat spiral spring. 14. The tensioner of claim 13 , wherein the biasing portion includes: a pair of axial-movement members disposed at two coil axis direction sides with respect to the flat spiral spring and coaxial to the flat spiral spring, the pair of axial-movement members each being supported so as to be displaceable in a coil axis direction with respect to the fixed section, and having an outer circumferential face that has a decreasing diameter on progression toward a coil axis direction center of the flat spiral spring and that contacts the plurality press-contact members from a radial direction inner side of the flat spiral spring; and a resilient member configured to bias the pair of axial-movement members in directions so as to approach each other. 15. The tensioner of claim 1 , wherein the resistance force imparting section includes: a back-up spring formed from plate-shaped spring material in an incomplete ring shape and having an outer circumferential face contacting an inner circumferential face of the flat spiral spring; a pair of axial-movement members disposed at two coil axis direction sides with respect to the flat spiral spring and coaxial to the flat spiral spring, the pair of axial-movement members each being supported so as to be displaceable in a coil axis direction with respect to the fixed section, and having an outer circumferential face that has a decreasing diameter on progression toward a coil axis direction center of