Rotary compressor with vane coupled to rolling piston

What is claimed is: 1. A compressor, comprising: a drive motor; a rotation shaft configured to transfer a rotation force of the drive motor, the rotation shaft having an eccentric portion; a cylinder provided at one side of the drive motor, and having a vane slot; a rolling piston coupled to the eccentric portion of the rotation shaft, and having a hinge recess at an outer circumferential surface of the rolling piston; and a vane having a vane body slidably inserted into the vane slot of the cylinder and a hinge protrusion inserted into the hinge recess of the rolling piston to be rotatable by a predetermined angle, wherein a diameter of the hinge protrusion is greater than an interval between both ends of an opening of the hinge recess, wherein the hinge protrusion includes: at least one bearing surface contacting an inner circumferential surface of the hinge recess provided on an outer circumferential surface of the hinge protrusion, wherein the at least one bearing surface is formed within a range of ±90 degree based on a central line in a lengthwise direction of the vane; and a plurality of spaced surfaces spaced from the inner circumferential surface of the hinge recess formed on the outer circumferential surface of the hinge protrusion as flat surfaces, and wherein at least two of the plurality of spaced surfaces are respectively formed between ends of the at least one bearing surface and side surfaces of the vane body respectively corresponding to the ends of the at least one bearing surface such that the at least two of the plurality of spaced surfaces are formed at sides of the vane body based on a virtual line that passes across a rotation center of the hinge protrusion and forms a right angle with respect to the central line in the lengthwise direction of the vane body. 2. The compressor of claim 1 , wherein the at least two of the plurality of spaced surfaces are respectively formed as a single flat surface or a plurality of continuous flat surfaces. 3. The compressor of claim 1 , wherein a groove concaved in a central direction of the vane is formed at a portion where the hinge protrusion starts, and wherein the groove is connected to the at least two of the plurality of spaced surfaces. 4. The compressor of claim 1 , wherein points at which the bearing surface and the at least two of the plurality of spaced surfaces meet each other are located on a line orthogonal to the central line in the lengthwise direction of the vane at a rotation center of the hinge protrusion. 5. The compressor of claim 1 , wherein the at least one bearing surface comprises a plurality of bearing surfaces and at least one spaced surface spaced from the inner circumferential surface of the hinge recess is formed between the plurality of bearing surfaces. 6. The compressor of claim 5 , wherein one of the plurality of bearing surfaces is formed at each of both sides based on on one side of the hinge protrusion with respect to the central line in the lengthwise direction of the vane and another of the plurality of bearing surfaces is formed on the other side of the central line. 7. The compressor of claim 1 , wherein the outer circumferential surface of the hinge protrusion comprises: aat least one first surface forming the at least one bearing surface; and second surfaces forming the at least two of the plurality of spaced surfacesand, the second surfaces extending from both ends of the at least one first surface and spaced apart from the hinge recess, wherein a circumferential angle between both the ends of the at least one first surface meeting one end of each of the second surfaces is 180° or less. 8. The compressor of claim 7 , wherein if a width of the vane is t, a vertical distance from the central line in the lengthwise direction of the vane to a point where a tilt surface and a second spaced surface of the second surfaces meet is α, a radius of curvature of a curved surface connecting the inner circumferential surface of the hinge recess and an the outer circumferential surface of the rolling piston is R 1 , a vertical distance from the central line in the lengthwise direction of the vane to a center of the curved surface is β, and a radius of curvature of the first surface is R, for R≥t/2, the vertical distance from the central line in the lengthwise direction of the vane to the point where the tilt surface and the second spaced surface of the second surfaces meet satisfies the relation of t/4<α<β-R 1 . 9. The compressor of claim 8 , wherein the second surfaces are formed by a plurality of flat surfaces, and wherein on a basis of a first virtual line connecting the rotation center of the hinge protrusion to a point where the first surface and a first spaced surface of the second surfaces meet, a tilt angle formed between the first virtual line and the first spaced surface of the second surfaces, is greater than an angle between the first virtual line and a second virtual line connecting the point where the first surface and the first spaced surface of the second surfaces meet to the point where the tilt surface and the second spaced surface of the second surfaces meet. 10. The compressor of claim 7 , wherein if a width of the vane is t, a vertical distance from the central line in the lengthwise direction of the vane to a point at which a tilt surface and a second spaced surface of the second surfaces meet is α, a radius of curvature of a curved surface connecting the inner circumferential surface of the hinge recess and an the outer circumferential surface of the rolling piston is R 1 , a vertical distance from the central line in the lengthwise direction of the vane to a center of the curved surface is β, and a radius of curvature of the first surface is R, for R<t/2, the vertical distance from the central line in the lengthwise direction of the vane to the point at which the tilt surface and the second spaced surface of the second surfaces meet satisfies the relation of t/4≤α<β-R 1 . 11. The compressor of claim 7 , wherein another end of a second spaced surface of the second surfaces meets a tilt surface formed as a flat surface at an end portion of the vane, and wherein an angle between the second spaced surface of the second surfaces and the tilt surface is equal to or greater than 90°. 12. The compressor of claim 7 , wherein the at least one first surface is provided in comprises a plurality of first surfaces, and at least one third surface is further formed between the plurality of first surfaces, the third surface being spaced apart from the inner circumferential surface of the hinge recess, and wherein a circumferential angle of the third surface based on the central line in the lengthwise direction of the vane is smaller than 90°. 13. A compressor, comprising: a drive motor; a rotation shaft configured to transfer a rotation force of the drive motor, the rotation shaft having an eccentric portion; a cylinder provided at one side of the drive motor; a rolling piston coupled to the eccentric portion of the rotation shaft, and having a hinge recess at an outer circumferential surface thereof; and a vane including a vane body slidably inserted into the cylinder, and a hinge protrusion rotatably inserted into the hinge recess of the rolling piston to be rotatable by a predetermined angle, wherein the hinge protrusion includes: at least one bearing surface provided on an outer circumferential surface of the hinge protrusion, wherein the at least one bearing surface is formed as a curved surface so as to slidably contact the an inner circumferential surface of the hinge recess; and a plurality of flat surfaces formed on the outer circumferential surface of th