Double eccentric valve

The invention claimed is: 1. A double eccentric valve comprising: a valve seat including a valve hole and a seat surface formed on an outer periphery of the valve hole; a valve element provided on its outer periphery with a sealing surface corresponding to the seat surface; and a rotary shaft including a leading end portion and a proximal end portion, the leading end portion being integrally provided with the valve element to rotate the valve element, in which an axial line of the rotary shaft extends in parallel to a radial direction of the valve element and the valve hole and is placed eccentrically from a center of the valve hole to another radial direction of the valve hole, and the sealing surface is positioned eccentrically from the axial line of the rotary shaft to a direction in which an axial line of the valve element extends such that the valve element is rotated by rotation of the rotary shaft between a fully-closed position where the valve element is seated on the valve seat and a fully-open position where the valve element is furthest away from the valve seat, wherein the double eccentric valve comprises: a drive source to generate a drive force to rotate the rotary shaft; a valve gear integrally provided with the proximal end portion of the rotary shaft to receive the drive force for rotating the rotary shaft; a bearing placed on a side of the proximal end portion of the rotary shaft to rotatably support the rotary shaft with the leading end portion thereof as a free end in cantilever configuration; a return spring to apply, to the valve gear, a spring force of rotating the rotary shaft in a direction to close the valve element; and a full-close stopper to which a part of the valve gear is contacted to restrict rotation of the valve gear with the rotary shaft while the valve element is placed in the fully-closed position, the bearing includes a first bearing and a second bearing placed on a side of the proximal end portion of the rotary shaft, the first bearing being placed in a position closer to the valve gear than the second bearing, the part of the valve gear is configured to be contacted with the full-close stopper by the spring force applied to the valve gear during non-driving of the drive source to apply the moment acting on the valve gear to the rotary shaft at the contact point of the valve gear with the full-close stopper as the fulcrum, so that the rotary shaft is tilted in its axial direction toward the valve seat to press the valve element against the valve seat with keeping a minute clearance from the second bearing at a contact point with the first bearing as the fulcrum, in a state where the valve element in the fully-closed position and where the valve gear fixed to the proximal end portion of the rotary shaft is seen from a side of the proximal end portion centering about the rotary shaft, when an orthogonal coordinate system is assumed with the axial line of the rotary shaft as the origin, an X axis as a horizontal direction, and a Y axis as a vertical direction, a first quadrant is a part defined by a +X axis and a +Y axis, a second quadrant is a part defined by a −X axis and the +Y axis, a third quadrant is a part defined by the −X axis and a −Y axis, and a fourth quadrant is a part defined by the +X axis and the −Y axis, the valve seat and the valve element are placed in the third quadrant and the fourth quadrant and the contact point of the part of the valve gear and the full-close stopper is placed in the first quadrant or the fourth quadrant such that the spring force acts in a direction to rotate the valve gear in a clockwise direction, the valve gear is provided with a teeth part including a plurality of teeth on a part of an outer periphery, the double eccentric valve comprises an intermediate gear to transmit the drive force of the drive source to the valve gear, and the valve element is configured to rotate between the fully-closed position in the third quadrant and the fourth quadrant and the fully-open position in the first quadrant and the fourth quadrant and a contact point of a part of the teeth part of the valve gear and a part of the intermediate gear is placed in the first quadrant or the fourth quadrant during rotation of the valve element. 2. A double eccentric valve comprising: a valve seat including a valve hole and a seat surface formed on an outer periphery of the valve hole; a valve element provided on its outer periphery with a sealing surface corresponding to the seat surface; and a rotary shaft including a leading end portion and a proximal end portion, the leading end portion being integrally provided with the valve element to rotate the valve element, in which an axial line of the rotary shaft extends in parallel to a radial direction of the valve element and the valve hole and is placed eccentrically from a center of the valve hole to another radial direction of the valve hole, and the sealing surface is positioned eccentrically from the axial line of the rotary shaft to a direction in which the axial line of the valve element extends such that the valve element is rotated by rotation of the rotary shaft between a fully-closed position where the valve element is seated on the valve seat and a fully-open position where the valve element is furthest away from the valve seat, wherein the double eccentric valve comprises: a drive source to generate a drive force to rotate the rotary shaft; a valve gear integrally provided with the proximal end portion of the rotary shaft to receive the drive force for rotating the rotary shaft and provided with a teeth part including a plurality of teeth on a part of an outer periphery; a bearing placed on a side of the proximal end portion of the rotary shaft to rotatably support the rotary shaft with the leading end portion thereof as a free end in cantilever configuration; a return spring to apply, to the valve gear, a spring force of rotating the rotary shaft in a direction to close the valve element; a full-close stopper to which a part of the valve gear is contacted to restrict rotation of the valve gear with the rotary shaft while the valve element is placed in the fully-closed position, and an intermediate gear to transmit the drive force of the drive source to the valve gear, the part of the valve gear is configured to be contacted to the full-close stopper by the spring force applied to the valve gear during non-driving of the drive source to apply the moment acting on the valve gear to the rotary shaft at a contact point of the valve gear with the full-close stopper as a fulcrum, so that the rotary shaft is tilted in its axial direction toward the valve seat to press the valve element against the valve seat at a contact point with the bearing as a fulcrum, a part of the teeth part of the valve gear is configured to be contacted with a part of the intermediate gear by the spring force applied to the valve gear during driving of the drive source to apply the moment acting on the valve gear to the rotary shaft at the contact point of the valve gear with the intermediate gear as the fulcrum, so that the rotary shaft is urged in a direction to be tilted in its axial direction toward the valve seat at the contact point with the bearing as the fulcrum, in a state where the valve element is placed in the fully-closed position and the valve gear fixed to the proximal end portion of the rotary shaft is seen from a side of the proximal end portion centering about the rotary shaft, when an orthogonal coordinate system is assumed with the axial line of the rotary shaft as the origin, an X axis as a horizontal direction, and a Y axis as a vertical direction, a first quadrant is a part defined by a +X axis and a +Y axis, a second quadrant is a part defined by a −X axis and the +Y axis, a third quadrant is a part defined by the −X axis and a −Y axis, and a fourth quadr