Impeller and cleaner using same

What is claimed is: 1 . A cleaner comprising: a main body through which air is exhausted from the cleaner, the main body including a filtration chamber and an exhaust chamber; a dust case connected to the main body; an air passage which is in the dust case and is extended from the dust case to the main body in an airflow direction; an impeller which rotates in the main body in a rotational direction and generates a suction force within the air passage in the airflow direction, the impeller comprising: a boss portion; a base portion extending in a radial direction from the boss portion, the base portion having a diameter which increases in the airflow direction; and blades extending in the radial direction from the boss portion, the blades including: a wind-cutting edge facing the airflow direction; and the wind-cutting edge including: a proximal end which is closest to the boss portion along the radial direction and meets the base portion; a protruding end which is furthest from the boss portion along the radial direction and is spaced apart from the base portion along the airflow direction; a protruding curved portion which is convexly curved in the rotational direction; and a recessed curved portion which is concavely curved in a direction opposite to the rotational direction, the recessed curved portion being closer to the protruding end of the wind-cutting edge than the protruding curved portion; and a motor which rotates the impeller, the impeller comprising a shaft which is connected to the impeller and rotates in the rotational direction. 2 . The cleaner of claim 1 , wherein based on a reference line which extends along the radial direction and connects the proximal end of the wind-cutting edge to the protruding end of the wind-cutting edge, the protruding curved portion of the wind-cutting edge protrudes from the reference line in the rotational direction and the recessed curved portion of the wind-cutting edge is recessed from the reference line in the direction opposite to the rotational direction. 3 . The cleaner of claim 1 , wherein a curvature of the recessed curved portion which is concavely curved is greater than a curvature of the protruding curved portion which is convexly curved. 4 . The cleaner of claim 1 , wherein a radius of curvature of the recessed curved portion which is concavely curved is less than a radius of curvature of the protruding curved portion which is convexly curved. 5 . The cleaner of claim 1 , wherein the base portion includes an inclined surface which outwardly slopes from the boss portion to define the diameter of the base portion which increases in the airflow direction; and the blades protrude from the inclined surface of the base portion, in a direction opposite to the airflow direction, and are tilted backward in the direction opposite to the rotational direction. 6 . The cleaner of claim 5 , wherein each of the blades which is tilted backward includes the protruding end of the wind-cutting edge behind the proximal end of wind-cutting edge with respect to the rotational direction. 7 . The cleaner of claim 6 , wherein each of the blades which is tilted backward further includes a major surface which faces in the rotational direction and is concavely curved. 8 . The cleaner of claim 6 , wherein based on a virtual line which corresponds to the proximal end of the wind-cutting edge and extends in the radial direction from the boss portion, the wind-cutting edge forms a swept-back angle of about 30 degree to about 50 degrees. 9 . The cleaner of claim 1 , wherein the wind-cutting edge is inclined in the airflow direction from the proximal end to the protruding end. 10 . The cleaner of claim 9 , wherein based on a virtual line which extends in the radial direction, the wind-cutting edge is inclined at an inclination angle of about 10 degrees to about 30 degrees. 11 . The cleaner of claim 1 , further comprising a shroud which is in the dust case and is extended from the dust case to the main body in the airflow direction, wherein the shroud comprises: a suction portion in which the motor is disposed, a moving blade portion in which the impeller is disposed, and a static blade portion, in order in the airflow direction; and an inner surface which defines the air passage and at which an inner diameter of the shroud is defined, the inner surface being defined at each of the suction portion, the moving blade portion and the static blade portion; wherein the inner diameter of the shroud at the suction portion decreases in the airflow direction and the inner diameter of the shroud at the moving blade portion increases in the airflow direction; within the moving blade portion, tips of the impeller face the inner surface of the shroud and are spaced apart from the inner surface by a tip clearance; and within the suction portion, the suction force moves air within the air passage along the radial direction in a direction away from the inner surface of the shroud. 12 . The cleaner of claim 1 , further comprising a controller which is connected to the motor and controls the motor, wherein the motor is in the dust cover, within the air passage; and within the air passage, the controller and the motor are in order in the airflow direction. 13 . The cleaner of claim 12 , wherein the suction force within the air passage draws air from outside the cleaner and into the air passage at the dust cover, through a cleaner head connected to the dust cover via the air passage; and within the air passage at the dust cover, the air from outside of the cleaner contacts the controller and the motor and air-cools the controller and the motor within the cleaner. 14 . An impeller of a cleaner, the impeller comprising: a boss portion at which the impeller is connected to a motor which rotates the impeller in a rotational direction to generate a suction force within an air passage of the cleaner, in an airflow direction; a base portion which is connected to the boss portion and extends in a radial direction from the boss portion, the base portion including an inclined surface which outwardly slopes from the boss portion to define a diameter of the base portion which increases in the airflow direction; blades which protrude from the inclined surface of the base portion, in a direction opposite to the airflow direction, and are tilted backward in a direction opposite to the rotational direction; and each of the blades having a swept-back wing shape defined by a wind-cutting edge facing the airflow direction, the wind-cutting edge including: a proximal end which is closest to the boss portion along the radial direction and meets the base portion; a protruding end which is furthest from the boss portion along the radial direction and is spaced apart from the base portion along the airflow direction; a protruding curved portion which is convexly curved in the rotational direction; and a recessed curved portion which is concavely curved in the direction opposite to the rotational direction, the recessed curved portion being closer to the protruding end of the wind-cutting edge than the protruding curved portion. 15 . The impeller of claim 14 , wherein based on a virtual line which corresponds to the proximal end of the wind-cutting edge and extends in the radial direction from the boss portion, the wind-cutting edge forms a swept-back angle of about 30 degree to about 50 degrees. 16 . The impeller of claim 15 , wherein the wind-cutting edge is inclined in the airflow direction from the pr