Rotary damper

The invention claimed is: 1. A rotary damper that generates braking torque against applied rotating force by limiting movement of viscous fluid, comprising: a case which has: a cylindrical chamber filled with the viscous fluid; and a partitioning part having a protruded shape which is formed along a center line of the cylindrical chamber and inward in a radial direction from an inner peripheral surface of the cylindrical chamber; a rotor which has: a rotor body received in the cylindrical chamber rotatably relative to the cylindrical chamber, so that an outer peripheral surface of the rotor body is close to an end surface of the partitioning part; and a vane formed along the center line of the cylindrical chamber and outward in a radial direction from the outer peripheral surface of the rotor body, so that an end surface of the vane is close to the inner peripheral surface of the cylindrical chamber; a lid which is fixed to an opening part of the cylindrical chamber, to confine the rotor together with the viscous fluid in the cylindrical chamber; a flow path, which is provided in the partitioning part or in the vane and connects regions in the cylindrical chamber partitioned by the partitioning part or the vane; a check valve, which is movably provided in the flow path, to close the flow path when the rotor rotates relative to the cylindrical chamber in a normal rotation direction and to open the flow path when the rotor rotates relative to the cylindrical chamber in a reverse rotation direction; and a reaction-force giving means, which generates reaction force to the check valve when the check valve moves to a prescribed position in a direction to close the flow path, wherein: the flow path has step structure in which a depth of a flow path part on a front side in the direction to close the flow path is shallower than a depth of a flow path part on a back side; and the reaction-force giving means has an elastic member which is attached to the check valve and abuts against a step surface due to the step structure of the flow path when the check valve moves in the direction to close the flow path, before the check valve closes the flow path. 2. A rotary damper of claim 1 , wherein: the reaction-force giving means further has a mounting means on which the elastic member is to be mounted; and the elastic member can be detached from the mounting means. 3. A rotary damper of claim 1 , further comprising: a sliding member which is attached to the vane and functions as a seal member closing a gap between the end surface of the vane and the inner peripheral surface of the cylindrical chamber, a gap between a lower surface of the vane and a bottom of the cylindrical chamber, and a gap between an upper surface of the vane and a lower surface of the lid. 4. A rotary damper of claim 2 , further comprising: a sliding member which is attached to the vane and functions as a seal member closing a gap between the end surface of the vane and the inner peripheral surface of the cylindrical chamber, a gap between a lower surface of the vane and a bottom of the cylindrical chamber, and a gap between an upper surface of the vane and a lower surface of the lid. 5. A rotary damper of claim 1 that generates braking torque against applied rotating force by limiting movement of viscous fluid, comprising: a case which has: a cylindrical chamber filled with the viscous fluid; and a partitioning part having a protruded shape which is formed along a center line of the cylindrical chamber and inward in a radial direction from an inner peripheral surface of the cylindrical chamber; a rotor which has: a rotor body received in the cylindrical chamber rotatably relative to the cylindrical chamber, so that an outer peripheral surface of the rotor body is close to an end surface of the partitioning part; and a vane formed along the center line of the cylindrical chamber and outward in a radial direction from the outer peripheral surface of the rotor body, so that an end surface of the vane is close to the inner peripheral surface of the cylindrical chamber; a lid which is fixed to an opening part of the cylindrical chamber, to confine the rotor together with the viscous fluid in the cylindrical chamber; a flow path, which is provided in the partitioning part or in the vane and connects regions in the cylindrical chamber partitioned by the partitioning part or the vane; a check valve, which is movably provided in the flow path, to close the flow path when the rotor rotates relative to the cylindrical chamber in a normal rotation direction and to open the flow path when the rotor rotates relative to the cylindrical chamber in a reverse rotation direction; and a reaction-force giving means, which generates reaction force to the check valve when the check valve moves to a prescribed position in a direction to close the flow path, wherein: the flow path has step structure in which a depth of a flow path part on a front side in the direction to close the flow path is shallower than a depth of a flow path part on a back side; and the reaction-force giving means has an elastic member which is attached to a step surface due to the step structure of the flow path and abuts against the check valve when the check valve moves in the direction to close the flow path, before the check valve closes the flow path. 6. A rotary damper of claim 5 , wherein: the reaction-force giving means further has a mounting means on which the elastic member is to be mounted; and the elastic member can be detached from the mounting means. 7. A rotary damper of claim 5 , further comprising: a sliding member which is attached to the vane and functions as a seal member closing a gap between the end surface of the vane and the inner peripheral surface of the cylindrical chamber, a gap between a lower surface of the vane and a bottom of the cylindrical chamber, and a gap between an upper surface of the vane and a lower surface of the lid. 8. A rotary damper of claim 6 further comprising: a sliding member which is attached to the vane and functions as a seal member closing a gap between the end surface of the vane and the inner peripheral surface of the cylindrical chamber, a gap between a lower surface of the vane and a bottom of the cylindrical chamber, and a gap between an upper surface of the vane and a lower surface of the lid.