Technical Field [0001] The present invention relates to a turbine that is used in, for example, a power-generating plant, a chemical plant, a gas plant, an iron mill, a ship, or the like. Priority is claimed on Japanese Patent Application No. 2010-209570 filed on September 17, 2010, the contents of which are incorporated herein by reference. Background Art [0002] As is well known, as a type of steam turbine, there is a steam turbine provided with a casing, a shaft body rotatably provided inside of the casing, a plurality of turbine vanes fixedly disposed at an inner peripheral portion of the casing, and a plurality of turbine blades radially provided at the shaft body at the downstream sides of the plurality of turbine vanes. In the case of an impulse turbine among such steam turbines, the pressure energy of steam is converted into velocity energy by the turbine vane and the velocity energy is converted into rotational energy (mechanical energy) by the turbine blade. Further, in the case of a reaction turbine, pressure energy is also converted into velocity energy by the turbine blade and the velocity energy is converted into rotational energy (mechanical energy) by a reaction force generated by the ejected steam. [0003] In this type of steam turbine, a gap is formed between a tip portion of the turbine blade and a casing that surrounds the turbine blade, thereby forming a flow path of steam, and a gap is also formed between a tip portion of the turbine vane and the shaft body. Leakage flow (leak steam) flows toward the downstream side from the upstream side of main flow in these gaps. However, if the leakage flow joins the main flow at the downstream side of the main flow, the flow of the main flow is disturbed, whereby loss (hereinafter referred to as "mixing loss") is generated, and thus turbine efficiency is reduced. [0004] In PTL 1 below, there is proposed a configuration in which a guide plate guiding leakage flow is mounted on a shroud at the outlet side of a flow path of the leakage flow among the above-described gaps, thereby making the direction of the leakage flow conform to the direction of main flow flowing out from the turbine blade. By such a configuration, a disturbance of the main flow that is generated at the time of joining of the leakage flow and the main flow is suppressed, and thus the mixing loss is reduced. Citation List Patent Literature [0005] [PTL 1] Japanese Unexamined Patent Application, First Publication No. 2007-321721 Summary of Invention Technical Problem [0006] However, in the related art, there is a problem in that a vortex of the leakage flow which agitates the main flow is formed at the downstream side of the above-described gap, and thus the mixing loss is generated. [0007] The present invention has been made in consideration of such circumstances and has an object of further reducing the mixing loss, thereby improving turbine efficiency. Solution to Problem [0008] According to an aspect of the present invention, a turbine includes a rotor that is rotatably supported; a stator provided around the rotor; a blade body having a blade provided at one of the rotor and the stator and extending in a radial direction toward the other side from one side and a shroud extending in a circumferential direction at a tip portion in the radial direction of the blade; and an accommodating concave body provided at the other of the rotor and the stator, extending in the circumferential direction, accommodating the shroud with a gap interposed therebetween, and relatively rotating with respect to the blade body; wherein leakage flow leaked from main flow flowing along the blade flows into the gap; and wherein the shroud is provided with a guide curved surface formed between a peripheral surface facing the accommodating concave body and a trailing edge end portion formed closer to the main flow side in a downstream of the leakage flow than the peripheral surface, a guide curved surface is configured to guide the leakage flow along the peripheral surface from the peripheral surface to the trailing edge end portion. [0009] According to this configuration, since the guide curved surface formed between the peripheral surface and the trailing edge end portion guides the leakage flow flowing along the peripheral surface, so as to cause the leakage flow to follow the guide curved surface from the peripheral surface to the trailing edge end portion, the leakage flow flows out from the trailing edge end portion to the main flow, whereby a vortex (hereinafter referred to as a "forward vortex") that is directed from the upstream side of the main flow to the downstream side at the boundary between a gap between the blade body and the accommodating concave body and a flow path of the main flow is formed. If the trailing edge end portion and the peripheral surface are continuous through a comer portion without having the guide curved surface, the leakage flow flowing along the peripheral surface is separated at the comer portion, and thus a reverse vortex flowing in the opposite direction to the forward vortex is formed. Since the reverse vortex flows back with respect to the main flow at the boundary between the gap and the flow path of the main flow and draws the main flow into the gap at a trailing edge of the shroud, the main flow is agitated. On the other hand, since the forward vortex that is formed by the above-described configuration does not flow back with respect to the main flow at the boundary between the gap and the flow path of the main flow and does not draw the main flow into the gap at the trailing edge of the shroud, the main flow is not agitated. Therefore, the generation of the mixing loss can be suppressed, and thus the turbine efficiency can be improved. [0010] Further, the trailing edge end portion may be made of an axial fin extending in a direction of a rotation axis. According to this configuration, since the trailing edge end portion is made of the axial fin extending in the direction of the rotation axis, the radial direction velocity component of the leakage flow guided to the trailing edge end portion is diminished. Thus, a difference between the radial direction velocity component of the main flow and the radial direction velocity component of the leakage flow becomes small. Therefore, since it is possible to make the leakage flow smoothly join the main flow, the mixing loss can be further reduced. [0011] Further, a guide pathway that performs guidance in the opposite direction to a relative rotation direction of the shroud with respect to the accommodating concave body may be formed on the guide curved surface, and in the guide pathway, an inflow portion allowing the leakage flow to flow into the guide pathway at the peripheral surface side and an outflow portion allowing the leakage flow to flow out of the guide pathway at the trailing edge end portion side may be shifted in the opposite direction to the relative rotation direction. According to this configuration, since the guide pathway that performs guidance in the opposite direction to the relative rotation direction of the shroud with respect to the accommodating concave body is formed, the circumferential direction velocity component in the opposite direction to the relative rotation direction is given to the circumferential direction velocity component of the leakage flow flowing in the relative rotation direction, whereby a difference between the circumferential direction velocity component of the leakage flow and the circumferential direction velocity component of the main flow can be reduced. Therefore, since it is possible to make the leakage flow smoothly join the main flow, the mixing loss can be further reduced. [0012] Further, the guide pathway may be formed in a groove shape. Further, the guide pathway may be formed by a protrusion wall protruding in the normal direction of the guide curved surface. According to this configuration, the guide pathway can be formed relatively easily. Further, in the guide curved surface, a cross-sectional contour of a cross-section of the guide curved surface along a plane intersecting the circumferential direction may be formed in an arc shape. Further, in the guide curved surface, a cross-sectional contour of a cross-section of the guide curved surface along a plane intersecting the circumferential direction may be formed in an elliptical shape. According to this configuration, the guide curved surface can be formed relatively easily. [0014] Further, the guide curved surface may be formed in a more concavo-convex shape compared to the surface of the blade at least. According to this configuration, since the guide curved surface is formed in a concavo-convex shape, the leakage flow flowing along the guide curved surface is turned into turbulent flow Thus, adherabihty of the leakage flow to the guide curved surface can be improved and it becomes difficult for the leakage flow to be separated from the guide curved surface. Thus, the leakage flow can be more reliably guided to the trailing edge end portion of the shroud. Effects of Invention [0015] According to the present invention, the mixing loss can be further reduced, and thus the turbine efficiency can be improved. Brief Description of Drawings FIG 1 is a cross-sectional view showing the schematic configuration of a steam turbine 1 according to a first embodiment of the present invention. FIG. 2 is a main section enlarged cross-sectional view showing a main section I in FIG. 1. FIG. 3 is an explanatory diagram of an operation of the steam turbine 1 and a main section enlarged view of a cross-section along a plane intersecting a circumferential direction. FIG. 4 is an explanatory diagram of an operation of the steam turbine 1 and an enlarged cross-sectional perspective view of a main section. FIG. 5A is a vector diagram showing main flow velocity V and leakage flow velocity v in the steam turbine 1. FIG. 5B is a vector diagram showing the main flow velocity V and the leakage flow velocity v in the steam turbine 1. FIG. 5C is a vector diagram showing the main flow velocity V and the leakage flow velocity v in the steam turbine 1. FIG. 6 is an enlarged cross-sectional view of a main section of a comparative example 01 of the steam turbine 1. FIG. 7 is an enlarged cross-sectional view of a main section of a modified example 1A of the steam turbine 1. FIG. 8 is an enlarged cross-sectional view of a main section of a steam turbine 2 according to a second embodiment of the present invention. FIG. 9 is an enlarged cross-sectional perspective view of a main section of the steam turbine 2. FIG. 10A is a vector diagram showing the main flow velocity V and the leakage flow velocity v in the steam turbine 2. FIG. 1 OB is a vector diagram showing the main flow velocity V and the leakage flow velocity v in the steam turbine 2. FIG. IOC is a vector diagram showing the main flow velocity V and the leakage flow velocity v in the steam turbine 2. FIG. 11 is an enlarged cross-sectional view of a main section of a modified example 2A of the steam turbine 2. FIG. 12 is an enlarged cross-sectional perspective view of a main section of a steam turbine 3 according to a third embodiment of the present invention. FIG. 13 is a blade row diagram of the steam turbine 3. FIG. 14A is a vector diagram showing the velocities of the main flow velocity V and the leakage flow velocity v in the steam turbine 3. FIG. 14B is a vector diagram showing the velocities of the main flow velocity V and the leakage flow velocity v in the steam turbine 3. FIG. 14C is a vector diagram showing the velocities of the main flow velocity V and the leakage flow velocity v in the steam turbine 3. FIG. 15 is an enlarged cross-sectional perspective view of a main section of a steam turbine 4 according to a fourth embodiment of the present invention. FIG. 16 is a blade row diagram of the steam turbine 4. FIG. 17A is a vector diagram showing the velocities of the main flow velocity V and the leakage flow velocity v in the steam turbine 4. FIG. 17B is a vector diagram showing the velocities of the main flow velocity V and the leakage flow velocity v in the steam turbine 4. FIG. 17C is a vector diagram showing the velocities of the main flow velocity V and the leakage flow velocity v in the steam turbine 4. FIG. 18 is an analysis result of a model 1 in which a guide curved surface 57 according to the invention is omitted. FIG. 19 is an analysis result of a model 2 in which the guide curved surface 57 according to the invention is formed. FIG. 20 is a graph showing turbine efficiency and a ratio of leakage flow rate to flow rate of main flow in the models 1 and 2 according to the invention. FIG 21 is a main section enlarged cross-sectional view showing an example in which the invention is applied to a turbine vane 40 and is equivalent to the main section J in FIG. 1. Description of Embodiments [0017] Hereinafter, embodiments of the invention will be described in detail referring to the drawings. (First Embodiment) FIG. 1 is a cross-sectional view showing the schematic configuration of a steam turbine (a turbine) 1 according to a first embodiment of the present invention. The steam turbine 1 mainly includes a casing (a stator) 10, an adjusting valve 20 that adjusts the amount and the pressure of steam S flowing into the casing 10, a shaft body (a rotor) 30 that is rotatably provided inward in the casing 10 and transmits power to a machine (not shown) such as an electric generator, a turbine vane 40 held in the casing 10, a turbine blade (a blade body) 50 provided at the shaft body 30, and a bearing unit 60 that supports the shaft body 30 so as to be able to rotate the shaft body 30 around an axis. [0018] The casing 10 has a hermetically sealed internal space and becomes a flow path of the steam S. The casing 10 has a ring-shaped divider outer ring (an accommodating concave body) 11 solidly fixed to the inner wall surface of the casing and surrounds the shaft body 30. [0019] The adjusting valve 20 is mounted in plural pieces in the inside of the casing 10 and each adjusting valve 20 includes an adjusting valve chamber 21 into which the steam S flows from a boiler (not shown), a valve body 22, and a valve seat 23, and if the valve body 22 is separated from the valve seat 23, a steam flow path is opened, and thus the steam S flows into the internal space of the casing 10 through a steam chamber 24. [0020] The shaft body 30 includes a shaft main body 31 and a plurality of disks 32 radially extending from the outer periphery of the shaft main body 31. The shaft body 30 is made so as to transmit rotational energy to a machine (not shown) such as an electric generator. The shaft body 30 passes through the divider outer ring 11 in the inside of the casing 10. [0021] The turbine vane 40 has a blade 49 radially extending toward the shaft body 30 from the divider outer ring 11, and a hub shroud 41 circumferentially extending at a tip portion in the radial direction of the blade 49. The turbine vane 40 is radially disposed in a large number so as to surround the shaft body 30, thereby configuring an annular turbine vane group, and each turbine vane 40 is held on the divider outer ring 11 described above. In each turbine vane 40, the hub shroud 41 is connected to be continuous in the circumferential direction and the hub shroud 41 connected in a ring shape on the whole faces the shaft body 30. The annular turbine vane group configured to be the plurality of turbine vanes 40 is formed by six at intervals in the direction of a rotation axis and made so as to guide the steam S to the turbine blade 50 side adjacent to the downstream side. [0022] The turbine blade 50 has a blade 59 radially extending toward the divider outer ring 11 from the shaft body 30, and a tip shroud (a shroud) 51 circumferentially extending at a tip portion in the radial direction of the blade 59. The turbine blade 50 is radially disposed in a large number on the downstream side of each annular turbine vane group, thereby configuring an annular turbine blade group, and each turbine blade 50 is solidly mounted on an outer peripheral portion of the disk 32 of the shaft body 30. Tip portions of the turbine blades 50 are connected by the tip shroud 51 made in a ring shape on the whole and face the divider outer ring 11. The annular turbine blade group and the annular turbine vane group constitute one stage by one set. That is, in the steam turbine 1, the annular turbine blade group and the annular turbine vane group are configured to be six stages. Then, a main flow M of the steam S is made so as to alternately flow through the turbine vane 40 and the turbine blade 50 in the direction of the rotation axis from the adjusting valve 20 side. In the following description, the direction of a rotation axis of the shaft body 30 is referred to as an "axial direction", the upstream side of the main flow in the axial direction is referred to as an "upstream side in the axial direction", and the downstream side of the main flow in the axial direction is referred to as a "downstream side in the axial direction". [0023] FIG 2 is a main section enlarged cross-sectional view showing a main section I in FIG. 1. As shown in FIG 2, step portions 52 A to 52C are formed on the tip side of the tip shroud 51. The step portions 52Ato 52C are formed in a staircase pattern such that a height from the blade 59 gradually increases toward the downstream side in the axial direction from the upstream side in the axial direction. In the step portions 52Ato 52C, outer peripheral surfaces (peripheral surfaces) 53Ato 53C each extending in the circumferential direction and also being perpendicular to the radial direction configure a stepped outer peripheral surface of the tip shroud 51. [0024] In the divider outer ring 11, an annular groove (an annular concave portion) 11A is formed at a site corresponding to the tip shroud 51, and the plurality of tip shrouds 51 connected in a ring shape is accommodated in the annular groove 11A in a state where a gap G is interposed therebetween. The gap G is a gap in which the cross-sectional shape of a cross-section perpendicular to the circumferential direction is formed in a U-shape (or an inverted U-shape), as shown in FIG. 2, and an axial gap ga formed between a leading edge 54 of the tip shroud 51 and an upstream groove side surface 11a of the divider outer ring 11 and an axial gap gb formed between a trailing edge 55 of the tip shroud 51 and a downstream groove side surface lib of the divider outer ring 11 are communicated with each other by a radial gap gc formed between the outer peripheral surfaces 53 (5 3 A to 53C) of the tip shroud 51 and a groove bottom lie of the divider outer ring 11. [0025] In order to seal the gap Q three seal fins 15 (15Ato 15C) extending so as to correspond one-to-one to the three step portions 52 (52Ato 52C) are disposed on the groove bottom lie in the annular groove 11A of the divider outer ring 11, and minute gaps H (HI to H3) are formed between the tips of the seal fins 15 (15Ato 15C) and the respective outer peripheral surfaces 53 (53Ato 53C). At the tip shroud 51, a guide curved surface 57 is formed between a trailing edge end portion 56 that is located on the main flow M side of the trailing edge 55 and comes into contact with the main flow M and the outer peripheral surface 53C of the step portion 52C. [0026] The guide curved surface 57 is formed such that the cross-sectional contour of a cross-section intersecting the circumferential direction has a quarter elliptical shape. The guide curved surface 57 is made such that a curvature radius increases as it proceeds toward the downstream side in the axial direction from a starting end (a terminus of the outer peripheral surface 53C) in the downstream in the axial direction of the minute gap H3, and connects the outer peripheral surface 53C and the trailing edge end portion 56. [0027] Returning to FIG 1, the bearing unit 60 includes a journal bearing apparatus 61 and a thrust bearing apparatus 62 and rotatably supports the shaft body 30. [0028] Next, an operation of the steam turbine 1 having the above-described configuration will be described using the drawings. FIG 3 is an explanatory diagram of an operation of the steam turbine 1 and a main section enlarged view of a cross-section intersecting the circumferential direction. First, if the adjusting valve 20 (refer to FIG 1) enters an open state, the steam S flows into the internal space of the casing 10 from a boiler (not shown). [0029] The steam S sequentially passes through the annular turbine vane group and the annular turbine blade group in each stage. At this time, pressure energy is converted into velocity energy by the turbine vane 40, most of the steam S passed through the turbine vane 40 flows between the turbine blades 50 constituting the same stage (the main flow M), and the velocity energy of the steam S is converted into rotational energy by the turbine blade 50, and thus a rotational force is applied to the shaft body 30. On the other hand, as shown in FIG. 3, some (for example, several %) of the steam S flows out from the turbine vane 40 and then flows into the gap G from the axial gap ga, thereby becoming leakage flow L. [0030] The leakage flow L reaches a cavity between the seal fins 15B and 15C through the minute gaps HI and H2. Then, the leakage flow L which has reached the cavity passes through the minute gap H3 so as to follow the outer peripheral surface 53C. [0031] The leakage flow L passed through the minute gap H3 flows to the downstream side in the axial direction along the outer peripheral surface 53C and then flows to the trailing edge end portion 56 in a state of being stuck to the guide curved surface 57. [0032] Fig. 4 is a main section enlarged cross-sectional perspective view for explaining an operation of the steam turbine 1 and FIG 5 is a vector diagram showing main flow velocity V and leakage flow velocity v in the steam turbine 1. Explaining the above-described operation in more detail, since the leakage flow L passed through the minute gap H3 does not apply rotational energy to the turbine blade 50, the leakage flow L retains most of the velocity energy applied thereto by the turbine vane 40. That is, a velocity component in the circumferential direction (a rotor rotation direction) becomes relatively large and the velocity component in the circumferential direction becomes larger than a circumferential direction velocity component of the turbine blade 50 (the tip shroud 51). Therefore, as shown in FIG. 4, the leakage flow L passed through the minute gap H3 flows radially inward and in the rotor rotation direction along the guide curved surface 57. Then, the leakage flow L flows out from the trailing edge end portion 56 to the main flow M passed through the turbine blade 50. At this time, as shown in FIGS. 5A to 5C, the main flow velocity V of the main flow M has only an axial velocity component, whereas the leakage flow velocity v of the leakage flow L has a circumferential direction velocity component ve (=vei) and a radial direction velocity component VR (=VRI). [0033] As shown in FIG 3, while some of the leakage flow L flowing out from the trailing edge end portion 56 to the main flow M is mixed with the main flow M, some other drifts toward the downstream side in the axial direction from the upstream side in the axial direction by the main flow M and then comes into contact with the downstream groove side surface lib of the annular groove 11 A, thereby flowing from a radially inward side to a radially outward side. In this manner, by the flow that is directed to the radially inward side along the guide curved surface 57, the flow that is directed to the downstream side in the axial direction along the main flow M, and the flow that is directed to the radially outward side substantially along the downstream groove side surface 1 lb, a forward vortex C flowing in the counterclockwise direction on the plane of paper of the drawing, as shown in FIG. 3, is formed in a space that is partitioned by the guide curved surface 57, the groove bottom lie, and the downstream groove side surface lib. Since the forward vortex C does not flow back into the main flow M at the boundary between the gap G and a flow path of the main flow (an arrow cl in FIG. 3) and does not draw the main flow M into the gap G along the trailing edge 55, the forward vortex C does not agitate the main flow M. In this way, the steam turbine 1 efficiently operates. [0034] As described above, according to the steam turbine 1, since the guide curved surface 57 formed between the outer peripheral surface 53C and the trailing edge end portion 56 guides the leakage flow L flowing along the outer peripheral surface 53C so as to cause the leakage flow L to follow the guide curved surface 57 from the outer peripheral surface 53C to the trailing edge end portion 56, the leakage flow L flows out from the trailing edge end portion 56 to the main flow M side, whereby the forward vortex C is formed. Since the forward vortex C does not flow back into the main flow M at the boundary between the gap G and the flow path of the main flow and does not draw the main flow M into the gap G along the trailing edge 55 of the tip shroud 51, the main flow M is not agitated. Therefore, the generation of mixing loss can be suppressed, and thus turbine efficiency can be improved. [0035] FIG 6 is an enlarged cross-sectional view of a main section of a comparative example 01 of the steam turbine 1. In addition, in the comparative example of FIG 6, a constituent element corresponding to that of the steam turbine 1 is denoted by the same sign. As shown in FIG 6, in a case where the outer peripheral surface 53C and the trailing edge end portion 56 are connected by an end face 057 intersecting the axial direction without forming the guide curved surface 57 therebetween, the leakage flow L flowing along the outer peripheral surface 53C is separated at a corner portion 057a that is formed between the end face 057 and the outer peripheral surface 53C. Then, the leakage flow L flows to the downstream side in the axial direction at approximately the same position as the outer peripheral surface 53C in the radial direction, reaches the downstream groove side surface lib, and is then directed to the radially inward side along the downstream groove side surface lib, whereby a reverse vortex X flowing in the opposite direction to the forward vortex C is formed. That is, if the leakage flow L flowing along the outer peripheral surface 53C is separated at a position separated from the main flow L, and thus the reverse vortex X is formed, the reverse vortex X flows back with respect to the main flow M at the boundary between the gap G and the flow path of the main flow (an arrow xl in FIG 6) and draws the main flow M into the gap G at the trailing edge 55 of the tip shroud 51 (an arrow x2), thereby agitating the main flow M to cause the mixing loss. [0036] However, since the forward vortex C that is formed by the configuration of the steam turbine 1 does not flow back with respect to the main flow M at the boundary between the gap G and the flow path of the main flow (the arrow cl in FIG 3) and does not draw the main flow M into the gap G along the trailing edge 55 of the tip shroud 51, the main flow M is not agitated and thus the generation of the mixing loss can be suppressed, and thus the turbine efficiency can be improved. [0037] In addition, in this embodiment, the guide curved surface 57 is formed such that the cross-sectional contour of the cross-section intersecting the circumferential direction has a quarter elliptical shape. However, the contour may also be an elliptical contour having a shape equivalent to another portion of an elliptical outer periphery. [0038] Further, as in a modified example 1A shown in, for example, FIG 7, a guide curved surface 57Amay also be formed in an arc shape (in the example of FIG 7, a quarter arc shape). Further, in this embodiment, the guide curved surface 57 is configured to connect the outer peripheral surface 53C and the trailing edge end portion 56. However, as in the modified example 1A shown in FIG 7, the guide curved surface 57A and the trailing edge end portion 56 may also be connected by an end face 58 intersecting the axial direction. That is, even if the guide curved surface 57 makes the leakage flow L reach the trailing edge end portion 56 along another surface (for example, the end face 58) after outflow from the guide curved surface 57A without having to make the leakage flow L follow only the guide curved surface 57 and having to be formed leakage flowso as to guide the leakage flow L to the trailing edge end portion 56, the same effect as the above-described effect can be obtained. That is, the guide curved surface 57A may be formed such that the leakage flow L finally reaches the trailing edge end portion 56 along another surface that is continuous with the guide curved surface 57A. In other words, a case where the guide curved surface 57A guides the leakage flow L flowing along the outer peripheral surface 53C, so as to follow the guide curved surface 57A and another surface from the outer peripheral surface 53C to the trailing edge end portion 56, is also included in the present invention. Further, in this embodiment, the outer peripheral surface 53C is formed so as to be perpendicular to the radial direction. However, the present invention can also be applied to an outer peripheral surface formed so as to gradually expand or reduce a diameter as it proceeds to the downstream side in the axial direction. That is, as long as the outer peripheral surface 53C intersects the radial direction, the present invention can be applied thereto. [0039] (Second Embodiment) Next, a steam turbine 2 according to a second embodiment of the present invention will be described using the drawings. FIG 8 is an enlarged cross-sectional view of a main section of the steam turbine 2 and FIG 9 is an enlarged cross-sectional perspective view of a main section of the steam turbine 2. In addition, in FIGS. 8 and 9, the same constituent elements as those in FIGS. 1 to 7 are denoted by the same signs and a description thereof is omitted here. [0040] As shown in FIG 8, the steam turbine 2 is different from the steam turbine 1 in terms of a trailing edge end portion 70 equivalent to the trailing edge end portion 56 of the steam turbine 1. The trailing edge end portion 70 is made of an axial fin extending from the tip shroud 51 to the downstream side in the axial direction, and thus the axial gap gb is narrowed. A tapered surface 70a that is connected to the guide curved surface 57 and also gradually directed to the radially inward side as it proceeds from the guide curved surface 57 to the downstream side in the axial direction is formed at the radially outward side of the trailing edge end portion 70. [0041] As shown in FIG 9, the leakage flow L passed through the minute gap H3 flows toward the trailing edge end portion 70 along the guide curved surface 57. The leakage flow L which has reached the trailing edge end portion 70 is guided by the trailing edge end portion 70, thereby greatly changing the direction of the flow to the downstream side in the axial direction, then flows along the tapered surface 70a, and flows out from the axial gap gb to the main flow M side. [0042] FIGS. lOAto IOC are vector diagrams showing the main flow velocity V and the leakage flow velocity v in the steam turbine 2. Explaining in more detail the above-described operation, the leakage flow L which has reached the trailing edge end portion 70 at leakage flow velocity vi [the radial direction velocity component VRI, the circumferential direction velocity component vei, and the axial direction velocity component 0] (refer to FIGS. 5 A to 5C) is guided by the trailing edge end portion 70, thereby flowing to the main flow M at leakage flow velocity V2 [a radial direction velocity component VR2, the circumferential direction velocity component vei, and an axial direction velocity component vzi]. That is, in the leakage flow L flowing out from the guide curved surface 57, while a portion of the radial direction velocity component VR is converted into an axial direction velocity component vz by the trailing edge end portion 70, and thus the radial direction velocity component VR significantly decreases from VRI to VR2 (refer to FIGS. lOAto 10C and FIGS. 5A and 5B), the axial direction velocity component vz increases from 0 to vzi (refer to FIGS. lOAto 10C and FIGS. 5B and 5C). [0043] Therefore, since the leakage flow L flows out from the trailing edge end portion 70 to the downstream side in the axial direction in a state where the axial direction velocity component has increased to vzi, the forward vortex C is strongly formed, thereby pushing the leakage flow L flowing along the guide curved surface 57 against the guide curved surface 57. Further, the radial direction velocity component VR decreases from VRI to VR2 and a difference of which with respect to the radial direction velocity component (~0) of the main flow M decreases. That is, the leakage flow L smoothly joins the main flow M while suppressing the agitation of the main flow M. [0044] As described above, according to the steam turbine 2, since the trailing edge end portion 70 is made of an axial fin extending in the axial direction, a portion of the radial direction velocity component VR is converted into the axial direction velocity component vz. Thus, the forward vortex C is strongly formed, thereby pushing the leakage flow L flowing along the guide curved surface 57 against the guide curved surface 57. Therefore, it becomes further difficult for the leakage flow L to be separated, and thus the effect of suppressing the agitation of the main flow M can be stably obtained. Further, since the trailing edge end portion 70 is made of the axial fin extending in the axial direction, the radial direction velocity component VR of the leakage flow L guided to the trailing edge end portion 70 is diminished. Thus, a difference between the radial direction velocity component (~0) of the main flow M and the radial direction velocity component VR (=VR2