Axial flow turbine

The invention claimed is: 1. An axial flow turbine comprising: a rotor extending along an axis; a plurality of rotating blades each having a rotating blade body extending from the rotor outward in a radial direction and a shroud provided at an outside end portion of the rotating blade body in the radial direction, and arranged at intervals in a circumferential direction; a casing surrounding the rotating blades from an outer side in the radial direction and having a recessed portion formed on an inner peripheral surface to accommodate the shrouds; a fin protruding from a facing surface of the recessed portion of the casing, which faces the shroud, inward in the radial direction, wherein a clearance is formed between the fin and an outer peripheral surface of the shroud; a stator blade support portion disposed close to a downstream end of the rotor with respect to the recessed portion on the inner peripheral surface of the casing; a plurality of stator blades each extending from the stator blade support portion inward in the radial direction and arranged at intervals in the circumferential direction; and an annular partition plate extending from a recessed portion downstream surface of the recessed portion, which is a surface on close to the downstream end of the rotor, toward an upstream end of the rotor and centered on the axis, wherein a bypass flow path, is formed in the casing, wherein the bypass flow path has a first end formed in the recessed portion downstream surface and a second end formed in the inner peripheral surface of the casing. 2. The axial flow turbine according to claim 1 , wherein the bypass flow path extends from an outside of the casing toward an inside thereof in the radial direction and from the upstream end of the rotor to the downstream end thereof, when viewed in a cross section that includes the axis. 3. The axial flow turbine according to claim 1 , wherein the bypass flow path is extended rearward in a rotation direction of the rotor as moving from the upstream end of the rotor to the downstream end thereof, when viewed from an outside of the casing in the radial direction. 4. The axial flow turbine according to claim 1 , wherein when a first dimension of the stator blade support portion in a direction of the axis is denoted by L and a second dimension from an upstream end edge of the stator blade support portion to a downstream end portion of the bypass flow path in the direction of the axis is denoted by A, a value of A/L satisfies a relationship of 0<A/L<0.15. 5. The axial flow turbine according to claim 1 , wherein when a first dimension of the stator blade support portion in a direction of the axis is denoted by L and a second dimension from an upstream end edge of the stator blade support portion to a downstream end portion of the bypass flow path in the direction of the axis is denoted by A, a value of A/L satisfies a relationship of 0.2<A/L<0.4. 6. The axial flow turbine according to claim 1 , wherein the recessed portion downstream surface is located close to the downstream end of the rotor with respect to an upstream end edge of the stator blade in a direction of the axis. 7. The axial flow turbine according to claim 1 , wherein a flow path cross-sectional area of the bypass flow path gradually decreases while going from the first end of the bypass flow path, which is an upstream end of the bypass flow path, toward the second end of the bypass flow path, which is a downstream end of the bypass flow path. 8. The axial flow turbine according to claim 1 , wherein the bypass flow path has a circular cross-sectional shape. 9. The axial flow turbine according to claim 1 , further comprising: a plurality of swirling prevention plates extending from an outer peripheral surface of the partition plate toward an inner peripheral surface of the recessed portion and arranged at intervals in the circumferential direction.