Optical diaphragm device, lens barrel, and imaging device or projection device

1 . An optical diaphragm device capable of changing an aperture diameter of a diaphragm aperture by advancing and retracting a plurality of blades with respect to an optical axis, the optical diaphragm device comprising: a plurality of diaphragm blades each including: a first blade portion which is formed of a first planar plate and shields light incident on the diaphragm aperture of the optical diaphragm device; a first fixing boss which protrudes from one surface of the first planar plate toward a side in a first direction along the optical axis; and a moving boss which protrudes from the other surface of the first planar plate toward a side in a second direction opposite to the first direction; a plurality of light leakage prevention blades each including: a second blade portion which is formed of a second planar plate and shields light incident on the diaphragm aperture of the optical diaphragm device; and a second fixing boss which protrudes from one surface of the second planar plate toward the side in the first direction, the light leakage prevention blade forming a pair with the diaphragm blade; a drive ring having a plurality of first cam grooves into each of which the moving boss is inserted, wherein a distance between the first cam groove and the optical axis differs corresponding to a position of the first cam groove, and the first cam groove is movable in a circumferential direction about the optical axis due to rotation of the drive ring about the optical axis; and a housing body capable of accommodating the diaphragm blades, the light leakage prevention blades, and the drive ring, wherein the optical diaphragm device includes a plurality of pairs each consisting of the diaphragm blade and the light leakage prevention blade, and a plurality of the first cam grooves each of which corresponds to each of the moving bosses are formed in the drive ring, a plurality of pairs each consisting of a first hole and a second hole are formed in the housing body corresponding to the plurality of pairs each consisting of the diaphragm blade and the light leakage prevention blade, the number of pairs each consisting of the first hole and the second hole being equal to the number of pairs each consisting of the diaphragm blade and the light leakage prevention blade, the first fixing boss and the second fixing boss being inserted into the pair of the first hole and the second hole respectively, a second cam groove is formed in the light leakage prevention blade, and the moving boss of the diaphragm blade is inserted into the second cam groove of the light leakage prevention blade, and is inserted into the first cam groove of the drive ring. 2 . The optical diaphragm device according to claim 1 , wherein with respect to a rotational direction of the drive ring, assuming a direction that the diaphragm blade is moved toward the optical axis by moving the first cam groove due to rotation of the drive ring as a diaphragm rotational direction, the diaphragm blade and the light leakage prevention blade which form a pair are disposed and the positional relationship between the pair consisting of the first hole and the second hole is established such that the second fixing boss of the light leakage prevention blade is positioned in front of the first fixing boss of the diaphragm blade in the diaphragm rotational direction. 3 . The optical diaphragm device according to claim 1 , wherein the housing body has a circular cylindrical outer peripheral wall having an inner side on which the diaphragm blade and the light leakage prevention blade are disposed, and a stepped portion having a drive ring placing surface on which the drive ring is placed is disposed on the inner side of the outer peripheral wall, the diaphragm blade has a first protruding portion where the first fixing boss is disposed, the first protruding portion protrudes from the first blade portion, the first protruding portion is positioned at a position remoter than an outer peripheral edge of the first blade portion with respect to a distance from the optical axis, and a recessed portion which at least a portion of the first protruding portion enters is formed in the stepped portion of the housing body. 4 . The optical diaphragm device according to claim 1 , wherein the housing body has a circular cylindrical outer peripheral wall having an inner side on which the diaphragm blade and the light leakage prevention blade are disposed, and a stepped portion having a drive ring placing surface on which the drive ring is placed is disposed on the inner side of the outer peripheral wall, the light leakage prevention blade has a second protruding portion where the second fixing boss is disposed, the second protruding portion protrudes from the second blade portion, the second protruding portion is positioned at a position remoter than an outer peripheral edge of the second blade portion with respect to a distance from the optical axis, and a recessed portion which at least a portion of the second protruding portion enters is formed in the stepped portion of the housing body. 5 . The optical diaphragm device according to claim 1 , wherein on the outer peripheral edge of at least one of the diaphragm blade and the light leakage prevention blade which form a pair, a recessed portion is formed by cutting away such that when the diaphragm blade and the light leakage prevention blade are moved to a position where the aperture diameter of the diaphragm aperture becomes maximum, the second fixing boss with respect to the diaphragm blade and the light leakage prevention blade which form another pair is disposed inside the recessed portion. 6 . The optical diaphragm device according to claim 1 , wherein with respect to a rotational direction of the drive ring, assuming a direction that the diaphragm blade is moved toward the optical axis by moving the first cam groove due to rotation of the drive ring as a diaphragm rotational direction, the first cam groove is formed at an angle inclined in a direction away from the optical axis as the first cam groove extends in the diaphragm rotational direction with respect to the circumferential direction about the optical axis, and an angle of the second cam groove with respect to the circumferential direction is set small compared to an angle of the first cam groove with respect to the circumferential direction. 7 . A lens barrel in which the optical diaphragm device according to claim 1 and a lens are housed. 8 . An imaging device or a projection device comprising: the optical diaphragm device according to claim 1 .