JP3967523B2 - Zoom adjustment mechanism - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a zoom adjustment mechanism for adjusting the magnification of an optical system such as binoculars.
[0002]
[Prior art]
There are binoculars with a zoom function that can continuously change the magnification.
In this type of binoculars, an objective lens or an eyepiece constituting a telescope optical system is accommodated in each of the left and right mirrors, and at least one of the objective lens and the eyepiece is composed of a plurality of lenses.
Then, when the objective lens is the front and the eyepiece lens is the rear, the zoom adjustment mechanism disposes the front lens group arranged near the front and the rear lens group among the plurality of lenses. The magnification is adjusted by changing the inter-lens distance of the rear group lens.
The zoom adjusting mechanism includes, for example, a cylindrical cam member centered on an axis extending in parallel with the optical axis, and two cams provided on the outer peripheral surface of the cam member so as to be movable in the axial direction. And two engaging members that engage with the groove. Each engaging member is coupled to a guide shaft provided in the optical axis direction via a bearing hole. The lens of the front group is connected to one engaging member, and the lens of the rear group is connected to the other engaging member, and each engaging member and the cam groove are configured to be engaged at one place. .
When the cam member is rotated, the two engaging members engaged with the cam grooves are moved in the opposite directions along the axial direction, so that the lenses are moved in the axial direction. ing.
[0003]
[Problems to be solved by the invention]
In the zoom adjustment mechanism in which each of the engaging members and the cam groove are engaged at one place, the inner peripheral surface of the bearing hole of each engaging member and the guide so that the engaging member can move along the guide shaft. A certain amount of gap is formed between the outer peripheral surfaces of the shafts. For this reason, when the cam member is rotated, the engaging member receives a force at one place where the engaging member is engaged with the cam groove. There is a possibility that the position of the engaging member in the axial direction may fluctuate due to contact. If the position of the engaging member varies, there arises a problem that the distance between the lenses of the front group and the rear group cannot be adjusted accurately, and zoom adjustment cannot be performed accurately.
The present invention has been devised in view of the above circumstances, and an object of the present invention is to provide a zoom adjustment mechanism capable of accurately performing zoom adjustment.
[0004]
[Means for Solving the Problems]
The present invention provides a zoom adjustment mechanism that adjusts the magnification of an image by changing a distance between lenses between a first lens and a second lens arranged on an optical axis, and an axis extending in parallel with the optical axis direction. A cylindrical outer peripheral surface centered on the axis, a cam member having a first cam groove and a second cam groove provided on the outer peripheral surface, and movable in the axial direction. And a first connecting portion that is non-rotatable in the direction around the axis and is engaged with the first cam groove and coupled to the first lens, and is movable in the axis direction and rotated in the direction around the axis A second connecting portion that is provided impossible and is engaged with the second cam groove and connected to the second lens; The first cam groove and the second cam groove are provided at different locations in the circumferential direction of the outer circumferential surface and in the same region of the outer circumferential surface in the axial direction, The first cam groove is composed of two grooves, a first front cam groove and a first rear cam groove, which have the same shape and are spaced apart from each other in the axial direction. It is characterized by comprising two grooves of a second front cam groove and a second rear cam groove having the same shape and spaced apart in the axial direction.
[0005]
Therefore, in the zoom adjustment mechanism of the present invention, the first connecting portion is engaged with the first front cam groove and the first rear cam groove spaced apart in the axial direction, and the second connecting portion is spaced in the axial direction. The second front cam groove and the second rear cam groove which are covered with each other are engaged with two places. As a result, the first and second connecting portions receive force from the cam member at two locations that are separated from each other in the axial direction.
Therefore, the force received by the first and second connecting portions from the cam member when the cam member is rotated as compared with the configuration in which the first and second connecting portions are respectively engaged with one place of the cam member. Therefore, the first and second connecting portions are prevented from rattling back and forth with respect to the axial direction. It is accurately moved in the direction.
As a result, the magnification of the image formed by the optical system including the first and second lenses is accurately adjusted by accurately adjusting the inter-lens distance between the first and second lenses according to the rotation amount of the cam member. Can be adjusted.
[0006]
Further, according to the zoom adjustment mechanism of the present invention, the first connecting portion is engaged with the two grooves of the first front cam groove and the first rear cam groove, and therefore always corresponds to the intermediate position between these two grooves. It is moved to the position. For this reason, the error in the position of the first connecting portion in the axial direction is an intermediate value of the error in the position of the two grooves in the axial direction.
Similarly, since the second connecting portion is engaged with the two grooves of the second front cam groove and the second rear cam groove, the second connecting portion is always moved to a position corresponding to an intermediate position between these two grooves. For this reason, the error in the position of the second connecting portion in the axial direction is an intermediate value between the errors in the positions of the two grooves in the axial direction.
That is, since the first and second connecting portions take a position corresponding to the intermediate position between the two cam grooves, the first and second connecting portions are compared with the case where only the first cam groove is engaged. 1. The error in the position of the second connecting portion is reduced. Accordingly, it is possible to improve the positional accuracy in the axial direction of the first and second connecting portions with respect to the rotation amount of the cam member.
As a result, the magnification of the image formed by the optical system including the first and second lenses is accurately adjusted by accurately adjusting the inter-lens distance between the first and second lenses according to the rotation amount of the cam member. Can be adjusted.
[0007]
Moreover, this invention can be set as the structure by which the said 1st cam groove and the 2nd cam groove are provided in the outer peripheral surface of the said cam member at intervals in the circumferential direction.
In the present invention, the cam member may be formed of a cylindrical body or a columnar body having the axis as a central axis.
According to the present invention, the first and second lenses constitute an eyepiece lens or an objective lens included in a telescope optical system, and the telescope optical system is provided in the left and right mirrors of binoculars, respectively. can do.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an external view showing a state in which a right eyepiece and a left eyepiece are closed and a right eyepiece and a left eyepiece are accommodated in an embodiment in which the zoom adjustment mechanism of the present invention is applied to binoculars. 1A is a plan view, FIG. 1B is a front view of FIG. 1A viewed from the direction of arrow A1, and FIG. 1C is a view of FIG. 1A viewed from the direction of arrow A2. FIG. 2 is an external view of binoculars showing the same state as FIG. 1, FIG. 2 (A) is a bottom view, and FIG. 2 (B) is a front view showing the state when FIG. 2 (A) is viewed from the direction of arrow A3. is there.
FIG. 3 is an external view showing a state in which the right and left eyepieces are opened and the right eyepiece and the left eyepiece are protruded in the embodiment of the binoculars of the present invention, and FIG. 3B is a front view showing the state of FIG. 3A viewed from the direction of the arrow B1, FIG. 3C is a side view of FIG. 3A viewed from the direction of the arrow B2, and FIG. (D) is the side view which looked at FIG. 3 (A) from the arrow B3 direction. 4 is an external view of binoculars showing the same state as FIG. 3, FIG. 4 (A) is a bottom view, FIG. 4 (B) is a rear view showing the state when FIG. 4 (A) is viewed from the direction of arrow B4, FIG. 4C is a side view showing the state of FIG. 4A viewed from the arrow B5.
[0009]
First, the overall configuration of binoculars will be described with reference to FIGS. 1 and 2.
In the following description, the left-right direction of the binoculars is defined in a state in which the direction where the objective lens of the binoculars is provided is the front and the direction where the eyepiece is provided is the rear.
The binoculars 1000 includes a support unit 100, an optical adjustment unit 200, a right mirror 300, and a left mirror 400.
The support part 100 is provided between the right mirror body 300 and the left mirror body 400 each having a telescope optical system, and supports them.
A diopter difference decorative ring 106 that is operated when performing diopter difference adjustment is attached to the support unit 100, and the optical adjustment unit 200 disposed in the support unit 100 includes these left and right telescope optical systems. A focus adjustment ring 202 that is operated when performing the focus adjustment and a zoom adjustment ring 204 that is operated when performing the magnification adjustment.
[0010]
The right mirror 300 and the left mirror 400 are supported by the support unit 100 so as to be movable in the width direction (left-right direction), that is, the eye width direction. Further, the support of the respective mirrors by the support unit 100 is performed so that the right mirror 300 and the left mirror 400 move in conjunction with each other by an equal distance from the support unit 100 around the support unit 100. Yes.
When the focus adjustment ring 202 is rotated, in the telescope optical system provided in the right mirror 300 and the left mirror 400, the same as the right moving body 303 and the right eyepiece 304 holding the eyepiece and the erecting prism. The left moving body 403 and the left eyepiece tube 404 that hold the eyepiece and the erecting prism are moved in the optical axis direction to perform focus adjustment.
Further, when the zoom adjustment ring 204 is rotated, some lenses of the telescope optical systems provided in the right mirror 300 and the left mirror 400 are moved in the direction of the optical axis so that the magnification is adjusted. It is configured. This magnification adjustment will be described in detail later.
[0011]
In addition, the focus adjustment ring 202 and the zoom adjustment ring 204 are provided adjacent to each other at a position closer to the eyepiece tube, that is, a position closer to the rear, on the center line in the horizontal direction of the binoculars 1000 when the binoculars 1000 are viewed from above. A focus adjustment ring 202 is provided at the front, and a zoom adjustment ring 204 is provided at the rear thereof so as to be rotatable about the same axis parallel to the optical axis of the telescope optical system. Further, the focus adjustment ring 202 and the zoom adjustment ring 204 are provided at a position of the support portion 100 facing above the binoculars 1000.
Since the axis and the optical axes of the left and right telescope optical systems are parallel, the “axial direction” and the “optical axis direction” mean the same direction. In the following description, the term “optical axis direction” will be used unless it is necessary to distinguish between “axial direction” and “optical axis direction”.
The diopter difference decorative ring 106 is provided at a position near the objective lens of the support part 100 facing the lower side of the binoculars 1000 on the center line in the left-right direction of the binoculars 1000 when viewed from above, that is, a position near the front. Yes.
Therefore, when the left and right mirrors are held by the left and right hands, the focus adjustment ring 202 and the zoom adjustment ring 204 are at the same distance from both the left and right hands, and therefore can be operated by either hand. The effect is also improved compared to the prior art.
[0012]
Next, the configuration of each part of the binoculars will be described.
5 is a partial cross-sectional view showing a state in which a part of the binoculars is broken, FIG. 6 is a cross-sectional view taken along the line XX of FIG. 5, and FIG. 7 is an exploded perspective view showing the overall configuration of the binoculars.
8 is an exploded perspective view showing a part of the support part, FIG. 9 is an exploded perspective view showing a part of the support part and the optical adjustment part, FIG. 10 is an exploded perspective view showing the configuration of the optical adjustment part, and FIG. It is a disassembled perspective view which shows a part of adjustment part and the structure of an upper board.
12 is an exploded perspective view mainly showing the structure of the right exterior part of the right mirror body, FIG. 13 is an exploded perspective view showing the structures of the right moving body, the right objective part, and the prism part, and FIG. 14 is the right mirror. It is a disassembled perspective view which mainly shows the structure of a 1st lens part, a 2nd lens part, and an eyepiece part of a body.
FIG. 15 is an exploded perspective view mainly showing the configuration of the left exterior part of the left mirror body, FIG. 16 is an exploded perspective view mainly showing the configuration of the left moving body, the left objective part, and the prism part of the left mirror body, and FIG. It is a disassembled perspective view which mainly shows the structure of a 1st lens part, a 2nd lens part, and an eyepiece part of a body.
[0013]
20A and 20B are views showing the structure of the main body, FIG. 18A is a plan view of the main body, FIG. 18B is a cross-sectional view showing a state in which the main body is broken along the longitudinal direction, and FIG. ) Is a bottom view of the main body. 19 is a cross-sectional view showing a state in which the main body is broken along a plane perpendicular to the longitudinal direction. FIG. 19A is a cross-sectional view taken along the line AA in FIG. 19B, and FIG. It is a BB line sectional view of B).
[0014]
20A and 20B are diagrams showing the configuration of the cam ring. FIG. 20A is a front view of the cam ring, FIG. 20B is a rear view of the cam ring, and FIG. 20C is AA in FIG. FIG. 20D is a cross-sectional view taken along line BB in FIG. 21A and 21B are diagrams showing the configuration of the cam groove provided on the outer periphery of the cam ring. FIG. 21A is a plan view and FIG. 21B is a development view of FIG.
[0015]
22 is a plan view of the cam frame, FIG. 23 is a front view of the cam frame showing the state when FIG. 22 is viewed from the direction of arrow E1, FIG. 24 is a cross-sectional view taken along line E2E2 of FIG. It is a rear view of the cam frame which shows the state seen from.
26 is a front view of the first lens piece, FIG. 27 is a right side view of the first lens piece showing the state of FIG. 26 as viewed from the direction of the arrow F1, and FIG. 28 is a first view of FIG. 29 is a bottom view of the lens piece, FIG. 29 is a sectional view taken along line F3F3 in FIG. 27, and FIG. 30 is a sectional view taken along line F4F4 in FIG.
31 is a front view of the second lens piece, FIG. 32 is a left side view of the second lens piece showing the state of FIG. 31 as viewed from the direction of arrow G1, and FIG. 33 is a second view of the state of FIG. 34 is a bottom view of the lens piece, FIG. 34 is a sectional view taken along line G3G3 of FIG. 32, and FIG. 35 is a sectional view taken along line G4G4 of FIG.
[0016]
FIG. 36 is a diagram showing the configuration of the first lens interlocking plate, FIG. 36 (A) is a front view of the first interlocking plate, and FIG. 36 (B) shows a state when FIG. 36 (C) is a bottom view of the first interlocking plate showing the state when FIG. 36 (A) is viewed from the arrow C, and FIG. 36 (D) is the arrow D of FIG. 20 (B). It is a side view which shows the state seen from. FIG. 37 is a view showing the configuration of the second lens interlocking plate, FIG. 37A is a front view of the second interlocking plate, and FIG. 37B is a state when FIG. FIG. 37 (C) is a bottom view of the second interlocking plate showing the state of FIG. 37 (A) viewed from the arrow C. FIG.
[0017]
FIG. 38 is a plan view of the optical adjustment unit showing the state in which the first and second lens interlocking plates are farthest apart and the telescope optical system is adjusted to the low magnification side. FIG. 39 is the first and second lens interlocking plates being the most. It is a top view of the optical adjustment part which shows the state which approached and the telescope optical system was adjusted to the high magnification side.
[0018]
First, the structure of a support part and an optical adjustment part is demonstrated with reference to FIG. 7 thru | or FIG.
The support unit 100 includes a frame 101, a support plate 102, a bottom lid 103, an upper plate 104, an interlocking gear 105, a right interlocking plate 109, a left interlocking plate 110, and the like. Further, a diopter difference decorative ring 106 and a diopter difference eccentric seat 107 that constitute a part of a diopter difference adjusting mechanism described later are attached to the bottom lid 103.
[0019]
The support plate 102 is formed in a rectangular plate shape, and is arranged so that the edge in the longitudinal direction is positioned before and after the binoculars, and the edge in the left and right direction perpendicular to the longitudinal direction is positioned on the left and right of the binoculars.
Two convex portions 102A1 and 102A2 are spaced in the front-rear direction in the vicinity of the right edge portion of the upper surface of the support plate 102, and similarly, the distance in the front-rear direction is increased in the vicinity of the left edge portion of the upper surface of the support plate 102. Two convex portions 102B1 and 102B2 are projected.
In addition, on the upper surface of the support plate 102, two convex portions 102B3 and 102A3 project on the center line in the left-right direction with a space in the front-rear direction, and a circular shape is formed between the front convex portion 102B3 and the front edge. A through hole 102C is provided, and a screw insertion hole 102D is provided between the two convex portions 102B3 and 102A3.
Further, in the vicinity of the front edge of the support plate 102, elongated holes 102H1 and 102I1 penetrating in the thickness direction are provided on the right side and the left side of the center line in the left and right direction so as to extend in the left and right direction, respectively. Similarly, in the vicinity of the rear edge of the support plate 102, elongated holes 102H2 and 102I2 penetrating in the thickness direction are provided on the right side and the left side of the center line in the left-right direction so as to extend in the left-right direction.
Further, the right edge of the support plate 102 is provided with notches 102J1 and 102J2 that are opened to the right with a space in the front-rear direction, and the left edge is opened to the left with a space in the front-rear direction. Notches 102K1 and 102K2 are respectively provided.
[0020]
The right interlocking plate 109 has a rectangular main body 109A and an extending portion 109B extending leftward from a position near the rear of the left edge of the main body 109A.
The front and rear edges of the main body 109A are provided with guide grooves 109A1 and 109A2 extending in the left-right direction through which the convex portions 102A1 and 102A2 are inserted, and the protruding portion 102B is provided with the convex portion 102A3. A guide groove 109B1 extending in the left-right direction is provided.
Further, screw insertion holes 109C1 and 109C2 are provided to penetrate the front and rear corners of the right edge of the main body 109A, and screw insertion holes 109D1 and 109D2 are provided to the front and rear corners of the left edge of the main body 109A. Is provided.
The intervals between the screw insertion holes 109C1 and 109C2 are the same as the intervals between the long holes 102H1 and 102H2 of the support plate 102, and the intervals between the screw insertion holes 109D1 and 109D2 are the same as the intervals between the notches 102J1 and 102J2 of the support plate 102. It is configured to be the same.
[0021]
The left interlocking plate 110 has a rectangular main body 110A and an extending part 110B extending rightward from a position closer to the front of the right edge of the main body 110A.
The front and rear edges of the main body 110A are provided with guide grooves 110A1 and 110A2 extending in the left-right direction through which the protrusions 102B1 and 102B2 are inserted, and the protrusion 110B3 is provided in the extension 110B. A guide groove 110B1 extending in the left-right direction is provided.
In addition, screw insertion holes 110C1 and 110C2 are provided to penetrate the front and rear corners of the left edge portion of the main body 110A, and screw insertion holes 110D1 and 110D2 are penetrated to the front and rear corners of the right edge portion of the main body 110A. Is provided.
The interval between the screw insertion holes 110C1 and 110C2 is configured to be the same as the interval between the long holes 102I1 and 102I2 of the support plate 102, and the interval between the screw insertion holes 110D1 and 110D2 is the same as the interval between the notches 102K1 and 102K2 of the support plate 102. It is configured to be the same.
[0022]
A rack 109B2 extending in the left-right direction at the front edge portion of the extending portion 109B of the right interlocking plate 109, and a rack extending in the left-right direction at the rear edge portion of the extending portion 110B of the left interlocking plate 110. 110B2 is formed.
The right interlocking plate 109 is screwed with a screw 802 through a washer 801 in a screw hole provided in each convex portion 102A1 to 102A3 in a state where the guide grooves 109A1, 109A2, and 109B1 are inserted into the convex portions 102A1 to 102A3, respectively. As a result, it is attached to the support plate 102 and supported so as to be movable in the left-right direction.
[0023]
The same applies to the left interlocking plate 110, with the guide grooves 110A1, 110A2, and 110B1 being inserted through the convex portions 102B1 to 102B3, respectively, through the washers 801 in the screw holes provided in the convex portions 102B1 to 102B3. When the screw 802 is screwed, it is attached to the support plate 102 and supported so as to be movable in the left-right direction.
The shaft portion of the screw 803 inserted from the lower surface side of the support plate 102 is inserted into the screw insertion hole 102D of the support plate 102, and the shaft portion is inserted through the center hole of the gear 105 on the upper surface side of the support plate 102. It is screwed into a screw hole 103A of the bottom lid 103 which will be described later.
The gear 105 is engaged with the racks 109B2 and 110B2 while being sandwiched between the racks 109B2 and 110B2 of the right interlocking plate 109 and the left interlocking plate 110 described above.
[0024]
The bottom cover 103 has a rectangular plate shape, and the longitudinal direction thereof is disposed above the support plate 102 along the front-rear direction.
The bottom cover 103 is positioned on the support plate 102 with the extension 109B of the right interlocking plate 109 and the extension 110B of the left interlocking plate 110 sandwiched between the lower surface and the upper surface of the support plate 102, which will be described later. In this manner, the frame 101 is fixed between the bottom of the frame 101 and the upper surface of the support plate 102.
[0025]
The positioning of the bottom lid 103 with respect to the support plate 102 is performed as follows.
That is, the left and right edge portions 103B closer to the front of the bottom cover 103 are fitted into the recessed grooves 102E extending in the front-rear direction on the left and right sides of the through hole 102C on the upper surface of the support plate 102, and the rear edge of the bottom cover 103 The left and right cutouts 103C are respectively fitted to left and right convex portions 102F provided so as to sandwich the left and right center line of the support plate 102 in the vicinity of the rear edge of the upper surface of the support plate 102. The bottom lid 103 is positioned on the support plate 102.
Further, screw insertion holes 102G penetrating in the vertical direction are provided at the centers of the left and right convex portions 102F, and screws 806 are inserted into these screw insertion holes 102G.
[0026]
The bottom cover 103 is provided with two protrusions 103D on the front side and two rear parts on the back side of the screw hole 103A so as to protrude downward in the thickness direction of the bottom cover 103.
Each convex part 103 </ b> D extends in a direction orthogonal to the longitudinal direction of the bottom cover 103, and is constituted by a strip-shaped part sandwiched by two long grooves formed so as to penetrate in the thickness direction of the bottom cover 103. The band plate-shaped portion is shaped so that the center in the longitudinal direction is curved downward in the thickness direction of the bottom lid 103.
These four convex portions 103D apply pressing force to the upper surfaces of the extension portion 109B of the right interlocking plate 109 and the extension portion 110B of the left interlocking plate 110, so that the right interlocking plate 109 and the left interlocking plate 110 move in the left-right direction. It is provided to give a frictional force when moving. This frictional force can improve the operational feeling at the time of moving the mirrors 300 and 400 to be described later in the left-right direction.
[0027]
According to the above configuration, since the rack 109B2 of the right interlocking plate 109 and the rack 110B2 of the left interlocking plate 110 are engaged with the gear 105, the right interlocking plate 109 and the left interlocking plate 110 approach in the left-right direction. Or move in conjunction with the direction of separation. Further, since the tooth pitches of the rack 109B2, the rack 110B2, and the gear 105 are configured to be the same, the right interlocking plate 109 and the left interlocking plate 110 are opposite to each other in the left-right direction around the rotation center of the gear 105. It is designed to move the same distance in the direction.
[0028]
Further, a through hole 103G is provided at a location sandwiched between the left and right convex portions 103B near the front side of the bottom lid 103.
The diopter difference decorative ring 106 includes a disc-shaped main body 106A having a diameter larger than the inner diameter of the through-hole 103G, a shaft portion 106B protruding upward from the upper center of the main body 106A, and an axial direction of the shaft portion 106B. The screw hole 106 </ b> C is provided along the line. As will be described later, the main body 106A is rotated around the axis of the shaft portion 106B to adjust the diopter difference.
In addition, two concave portions 106D are provided around the shaft portion 106B with the shaft portion 106B interposed therebetween, and an arc-shaped concave groove 106E is formed along the circumferential direction of the shaft portion 106B.
Here, if there are at least one concave portion 106D and at least one convex portion 107C, axial rotation drive can be transmitted.
[0029]
The diopter difference eccentric seat 107 includes a disc-shaped main body 107A having a diameter larger than the inner diameter of the through hole 103G, an eccentric hole 107B penetrating in the thickness direction at a position eccentric from the center of the main body 107A, and a diopter difference makeup. Two convex portions 107C that fit into the two concave portions 106D of the ring 106 are provided.
[0030]
The shaft portion 106B of the diopter difference decorative ring 106 is inserted into the through hole 103G from below the back cover 103, and is inserted into the eccentric hole 107B of the diopter difference eccentric seat 107. In this state, the two convex portions 107C of the diopter difference eccentric seat 107 are fitted in the two concave portions 106D of the diopter difference decorative ring 106, respectively. Then, a screw 805 is inserted into the eccentric hole 107B of the diopter difference eccentric seat 107 via a spring washer 804, and a shaft portion of the screw 805 is formed in a shaft portion 106B of the diopter difference decorative ring 106. The diopter difference eccentric seat 107 is attached to the diopter difference decorative ring 106 via the bottom lid 103.
Further, as shown in FIG. 6, in this state, the main body 106A of the diopter difference decorative ring 106 faces outward from the lower surface of the support plate 102 through the through hole 102C of the support plate 102. It has become.
The diopter difference decorative ring 106 attached to the diopter difference eccentric seat 107 is located at a position closer to the front side on the center line in the left-right direction of the support plate 102.
[0031]
Further, a ridge extending in the circumferential direction of the through-hole 103G is formed on the peripheral edge of the through-hole 103G on the lower surface of the bottom lid 103, and is fitted to the concave groove 106E on the upper part of the diopter difference decorative ring 106 In such a state, it is configured to be rotatable. The rotation amount of the diopter difference decorative ring 106 is regulated by the circumferential end of the concave groove 106E of the diopter difference decorative ring 106 coming into contact with the peripheral end of the ridge. .
The diopter difference decorative ring 106 and the diopter difference eccentric seat 107 are integrally fixed in the rotational direction of the shaft portion 106B by fitting the concave portion 106D and the convex portion 107C, but the axial direction of the shaft portion 106B. Are configured to be movable with respect to each other.
[0032]
In addition, a click engagement portion 103H having a plurality of concave and convex shapes extending at intervals in the circumferential direction of the through hole 103G is formed at the peripheral portion of the through hole 103G on the upper surface of the back cover 103, and the difference in visibility When the eccentric seat 107 is rotated, the convex portion provided on the lower surface of the diopter difference eccentric seat 107 is engaged with and disengaged from the click engaging portion 103H, so that the diopter difference decorative ring 106 is rotated. When it comes to giving a click feeling. At this time, the spring washer 804 functions to press the lower surface of the main body 107A of the diopter difference eccentric seat 107 toward the click engaging portion 103H.
[0033]
As shown in FIGS. 9, 10, 18, and 19, the frame 101 connects the rectangular front wall 101A and the rear wall 101B, and the right and left sides of the front wall 101A and the rear wall 101B. The rectangular right wall 101C and the left wall 101D are configured. The top and bottom of the frame 101 are opened in a rectangular shape.
The bottom of the frame 101 is attached to the support plate 102 in a state covered with the bottom lid 103. That is, the four screws 806 are respectively screwed into the four screw holes 101E formed at the four corners of the bottom of the frame 101 through the four screw insertion holes 102G formed in the support plate 102.
[0034]
The upper plate 104 has a rectangular plate shape that is substantially the same size as the support plate 102, and the longitudinal edges are in front of and behind the binoculars edges, and the lateral edges perpendicular to the longitudinal direction are on the left and right sides of the binoculars. It arrange | positions so that it may be located. That is, the upper plate 104 extends in the optical axis direction of the telescope optical system and in the left-right direction orthogonal to the optical axis direction.
The upper plate 104 is attached so as to close the upper opening 101K of the frame 101. That is, the four screws 807 are respectively screwed into the four screw holes 101 </ b> F formed in the upper four corners of the frame 101 through the four screw insertion holes 104 </ b> A formed in the upper plate 104.
Window portions 104A and 104B are provided at positions closer to the rear on the center line in the left-right direction of the upper plate 104 so that a part of the outer periphery of the focus adjustment ring 202 and the zoom adjustment ring 204 described later face outward. It has been.
A rectangular decorative plate 101I and a name plate 101J are bonded to the front surface of the front wall 101A and the rear surface of the rear wall 101B of the frame 101, respectively.
[0035]
According to the support unit 100 described above, the frame 101, the support plate 102, the bottom lid 103, and the upper plate 104 are integrally fixed. The right interlocking plate 109 and the left interlocking plate 110 are supported by the support plate 102 so as to be movable in the left-right direction.
[0036]
Next, the configuration of the optical adjustment unit 200 will be described.
The optical adjusting unit 200 includes a main shaft 201, a focus adjusting ring 202, a zoom adjusting ring 204, a moving shaft 206, a cam ring 207 (corresponding to the cam member in the claims), a first lens frame, which are incorporated in the frame 101 described above. 208 (first frame of claims, first Linking The second lens piece 209 (the second piece in the claims, the second piece) Linking The cam frame 210, the frame guide shafts 211 and 212, the first lens interlocking plate 213 (the first of the claims) Linking Part 1 Linking The second lens interlocking plate 214 (corresponding to the member) 2 connections Part 2 Linking Equivalent to a member), a presser plate (blade) 215, a mirror interlocking shaft 216, and the like.
[0037]
The main shaft 201 extends so that its axis is parallel to the optical axes of the right and left telescope optical systems accommodated in mirror bodies 300 and 400, which will be described later. It is pivotally supported by bearings 101A1 and 101B1 provided on the front wall 101A and the rear wall 101B.
The main shaft 201 is configured such that the position in the left-right direction of the axis coincides with the center position in the left-right direction of the frame 101. The main shaft 201 is configured such that the vertical position of its axis is above the vertical position of the optical axis of the left and right telescope optical systems, which will be described later.
The focus adjustment ring 202 and the zoom adjustment ring 204 are provided so as to be rotatable about the axis of the main shaft 201. Further, the above-described diopter difference decorative ring 106 is provided so as to be rotatable about an axis perpendicular to the axis of the main shaft 201.
On the outer peripheral surface of the front end portion of the main shaft 201, recessed grooves 201A extending along the axial direction are formed at intervals in the circumferential direction. This concave groove 201A is adapted to be fitted into a ridge 207B formed in a hole 207A of a cam ring 207 described later.
[0038]
The zoom adjustment ring 204 includes a main body 204A formed in an annular shape and a rubber ring 204B attached to the outer periphery of the main body 204A.
The main body 204A is integrally attached to the main shaft 201 with a screw 808 in a state where the rear end portion of the main shaft 201 is inserted into the hole 204A1 on the inner peripheral portion thereof.
[0039]
Next, the cam ring 207 will be described with reference to FIGS.
The cam ring 207 is formed of a cylindrical body including a cylindrical wall portion 201C centering on an axis of the main shaft 201 (corresponding to an axis extending in parallel with the optical axis direction in the claims). A cylindrical outer peripheral surface 207C1 is formed on the outer side.
An annular wall portion 207A is provided on one side in the central axis direction of the wall portion 201C of the cam ring 207.
In the hole 207A1 penetrating through the center of the wall portion 207A, a protrusion 207B that fits into the groove 201A of the main shaft 201 described above is formed along the central axis, and the main shaft 201 is formed in the hole 207A1. The main shaft 201 is supported by the main shaft 201 so as to be movable along the main shaft 201 while being inserted, and not rotatable in the circumferential direction of the main shaft 201.
That is, the cam ring 207 is attached to the main shaft 201 so as not to rotate in the axial direction of the main shaft 201.
[0040]
Further, among the edge portions on the other side of the wall portion 207 </ b> C in the central axis direction, bearing portions 207 </ b> F are provided so as to protrude toward the central axis from two symmetrical positions across the central axis.
The bearing portion 207F is formed in an arc shape corresponding to the outer periphery of the second shaft portion 206B of the moving shaft 206 described later. The bearing portion 207F is supported so as to be rotatable with respect to the second shaft portion 206B of the moving shaft 206.
[0041]
A first cam groove 207D and a second cam groove 207E are formed on the outer peripheral surface 207C1 of the cam ring 207.
The first cam groove 207D is composed of two grooves of a first front cam groove 207D1 and a first rear cam groove 207D2 that have the same shape and are spaced apart from each other in the axial direction.
The second cam groove 207E is also composed of two grooves, the second front cam groove 207E1 and the second rear cam groove 207E2, which have the same shape and are spaced apart from each other in the axial direction.
[0042]
As shown in FIG. 21, the first cam groove 207D and the second cam groove 207E are provided on the outer peripheral surface 207C of the cam ring 207 at intervals in the circumferential direction. That is, the first cam groove 207D and the second cam groove 207E are provided in the same region of the outer peripheral surface 207C in the direction around the central axis of the cam ring 207, that is, the axis of the main shaft 201.
Further, the two first cam grooves 207D and the two second cam grooves 207E extend in a direction crossing each other on the outer peripheral surface 207C1 of the cam ring 207.
[0043]
As shown in FIGS. 9 and 10, the moving shaft 206 includes a cylindrical first shaft portion 206 </ b> A provided on the rear side, a second shaft portion 206 </ b> B provided on the front side, A flange portion 206C formed between the second shaft portions, and a hole portion 206D that penetrates the first shaft portion 206A, the flange portion 206C, and the second shaft portion 206B in the axial direction of the moving shaft 206 are configured. ing.
The inner diameter of the hole 206D is formed so that the main shaft 201 can rotate while the main shaft 201 is inserted.
[0044]
A spiral guide groove 206A1 is formed on the outer peripheral surface of the first shaft portion 206A. The guide groove 206A1 includes a first groove portion 206A11 having a wide pitch in the axial direction of the first shaft portion 206A in order from the front. The second groove portion 206A12 is connected to the first groove portion 206A11 and has a narrow pitch in the axial direction of the first shaft portion 206A.
The focus adjustment ring 202 includes an annular main body 202A and a rubber ring 202B attached to the outer periphery of the main body 202A.
Further, the outer diameters of the focus adjustment ring 202 and the zoom adjustment ring 204, that is, the outer diameters of the rubber rings 202B and 204B are configured to be substantially the same.
On the inner peripheral surface 202A1 of the main body 202A, a holding portion 202A11 that holds the two spheres 203 that engage with the guide groove 206A1 in a rotatable manner and that cannot move around the axis is opposed to each other around the axis. Is provided.
[0045]
Next, the cam frame 210 will be described with reference to FIGS.
The cam frame 210 includes an annular portion 210A having a substantially C shape disposed with its opening facing upward as viewed from the front, and a right arm portion 210B and a left arm portion extending rearward from the opening portion of the annular portion 210A. 210C and the connection arm part 210D extended backward from the lower part of the annular part 210A.
[0046]
As shown in FIG. 25, shaft holding holes 210A1 and 210A2 facing rearward are provided at left and right symmetrical positions of the portion facing the rear of the annular portion 210A. The shaft holding holes 210A1 and 210A2 are configured to hold the top guide shafts 211 and 212 shown in FIG. 12 in a state of extending in parallel with the axis.
A first lens frame 208 and a second lens frame 209, which will be described later, are provided to be movable along the frame guide shafts 211 and 212, respectively.
[0047]
Further, screw holes 210B1 and 210C1 facing rearward are provided at rear end portions of the right arm portion 210B and the left arm portion 210C of the annular portion 210A. Further, a screw hole 210D1 facing rearward is provided in a portion facing the rear of the connecting arm portion 210D. Screws 809 inserted through screw insertion holes 206C1, 206C2, and 206C3 provided in the flange portion 206C of the moving shaft 206 are screwed into the screw hole holes 210B1, 210C1, and 210D1, respectively, so that the cam ring 210 is moved to the moving shaft. 206 is attached. Further, a screw hole 210D2 facing downward is provided at the rear end portion of the connecting arm portion 210D.
[0048]
Projection pieces 206C4 and 206C5 project from the right and left edges of the flange portion 206C of the moving shaft 206, respectively, and these projection pieces respectively contact the right wall 101C and the left wall 101D of the frame 101. By being supported so as to be movable in the axial direction in contact with each other, the moving shaft 206 and the cam frame 210 are supported so as to be movable in the axial direction (front-rear direction) of the main shaft 201 and non-rotatable around the axis.
[0049]
As shown in FIGS. 11, 38, and 39, the second shaft portion 206 </ b> B of the moving shaft 206 is inserted into the wall portion 207 </ b> C of the cam ring 207, and the bearing portion 207 </ b> F is connected to the moving shaft 206. The cam ring 207 is rotatably provided with respect to the second shaft portion 206B by supporting the second shaft portion 206B.
The cam ring 207 is disposed so that the outer peripheral surface 207C1 is surrounded by the right arm portion 210B, the left arm portion 210C, and the connecting arm portion 210D of the cam frame 210 at intervals.
As will be described later, the first and second lens pieces 208 and 209 are provided on the outer peripheral surface of the right arm portion 210B, the left arm portion 210C, the connecting arm portion 210D of the cam frame 210 and the outer peripheral surface 207C1 of the cam ring 207. It is provided so as to be movable in the axial direction between them and immovable in the direction around the axial line.
[0050]
Next, the first lens piece 208 and the second lens piece 209 will be described with reference to FIGS. 26 to 30 and FIGS. 31 to 35.
As shown in FIGS. 26 to 30, the first lens piece 208 has a cylindrical wall-shaped main body 208A that extends around the axis of the main shaft 201 and has a thickness in a direction perpendicular to the axis. Yes. When the surface facing the cam ring 207 of the main body 208A is the inner side surface and the opposite surface is the outer side surface, the two bearing portions 208B and 208C provided on the outer surface of the main body 208A with a space in the axial direction. And a mounting portion 208D to which a first lens interlocking plate 213, which will be described later, is attached is provided below the outer surface of the main body 208A.
The bearing portions 208B and 208C are provided with bearing holes 208B1 and 208C1 through which the top guide shaft 212 is inserted. A predetermined gap is formed between the inner peripheral surface of the bearing holes 208B1 and 208C1 and the outer peripheral surface of the top guide shaft 212 so that the bearing portions 208B and 208C can move.
The mounting portion 208D is provided with a screw hole 208D1 facing downward.
[0051]
On the inner surface of the main body 208A of the first lens piece 208, a spherical surface 210B that engages with the first front cam groove 207D1 of the cam ring 207 is rotatably held between the first front cam groove 207D (rotatable). Between the first front sphere holding portion 208A1 (corresponding to the first front engagement portion in the claims) and the sphere 210B engaging with the first rear cam groove 207D2 between the first rear cam groove 207D2 The first rear sphere holding portion 208A2 (corresponding to the first rear engagement portion in the claims) that presents a spherical concave portion that can be rotated (rotatably) is positioned on the same straight line that is parallel to the axis. It is provided to do.
[0052]
As shown in FIGS. 31 to 35, the second lens piece 209 has a cylindrical wall-shaped main body 209A extending around the axis of the main shaft 201 and having a thickness in a direction perpendicular to the axis. Yes. Then, when the surface facing the cam ring 207 of the main body 209A is the inner surface and the opposite surface is the outer surface, the two bearing portions 209B and 209C provided on the outer surface of the main body 209A with a space in the axial direction. And a mounting portion 209D to which a later-described second lens interlocking plate 214 is attached is provided at the lower portion of the outer surface of the main body 209A.
Bearing holes 209B1 and 209C1 through which the top guide shaft 211 is inserted are provided in the bearing portions 209B and 209C, respectively. A predetermined gap is formed between the inner peripheral surface of the bearing holes 209B1 and 209C1 and the outer peripheral surface of the top guide shaft 211 so that the bearing portions 209B and 209C can move. This is similar to the case of the lens piece 208.
The attachment portion 209D is provided with a screw hole 209D1 facing downward.
[0053]
On the inner side surface of the main body 209A of the second lens piece 209, a spherical surface 210B that engages with the second front cam groove 207E1 of the cam ring 207 is rotatably held between the second front cam groove 207E1 (rotatable). Between the second front sphere holding portion 209A1 (corresponding to the second front engagement portion in the claims) and the sphere 210B engaging with the second rear cam groove 207E2 between the second rear cam groove 207E2. The second rear sphere holding portion 209A2 (corresponding to the second rear engagement portion in the claims) that presents a spherical concave portion that can be rotated (rotatably) is positioned on the same straight line that is parallel to the axis. It is provided to do.
[0054]
That is, the first lens piece 208 is engaged with the first front cam groove 207D1 and the first rear cam groove 207D2 via each sphere 210B, and the second lens piece 209 is engaged with the second front cam groove 207E1 via each sphere 210B. The second rear cam groove 207E2 is engaged.
Then, when the main shaft 201 rotates, the cam ring 207 rotates inward of the right arm portion 210B, the left arm portion 210C, and the connecting arm portion 210D of the cam frame 210, the first front cam groove 207D1 of the cam ring 207, the first The rear cam groove 207D2, the second front cam groove 207E1, and the second rear cam groove 207E2 rotate with respect to the cam frame 210. By rotating these four cam grooves, the first lens piece 208 and the second lens piece 209 are rotated in the cam frame 210 while the sphere 210B held by each holding portion 208A1, 208A2, 209A1, 209A2 is rotated. It moves along the axial direction along 212 and 211.
[0055]
Here, as described above, the two first cam grooves 207D and the two second cam grooves 207E extend in a direction crossing each other on the outer peripheral surface 207C1 of the cam ring 207, whereby the first lens frame 208 and The second lens pieces 209 are moved in directions opposite to each other along the axial direction, that is, in a direction of approaching and separating.
That is, when the cam ring 207 is rotated in a predetermined direction around the axis, the first lens piece 208 and the second lens piece 209 are moved in a direction approaching each other, and the cam ring 207 is in a direction opposite to the predetermined direction around the axis. The first lens piece 208 and the second lens piece 209 are moved away from each other.
As described above, the first cam groove 207D and the second cam groove 207E are provided in the same region in the direction around the axis of the outer peripheral surface 207C of the cam ring 207. Therefore, the first lens frame 208 and the second lens frame 209 are provided. , The movement ranges in the axial direction due to the rotation of the cam ring 207 overlap each other.
[0056]
According to the configuration described above, the first lens piece 208 is engaged with the first front cam groove 207D1 and the first rear cam groove 207D2 spaced apart in the axial direction, and the second lens piece 209 is spaced apart in the axial direction. The second front cam groove 207E1 and the second rear cam groove 207E2 are engaged with each other.
As a result, the first and second lens pieces 208 and 209 receive the force from the cam ring 207 at two locations separated in the axial direction.
Therefore, as described above, even if a gap is formed between the bearing holes of the first and second lens pieces 208 and 209 and the piece guide shaft, the first and second portions can be used when the cam ring 207 is rotated. The lens frames 208 and 209 are restrained from tilting with respect to the axial direction by the force received from the cam ring 207, and the back and forth of the first and second lens frames 208 and 209 is prevented. The second lens pieces 208 and 209 are accurately moved in the axial direction corresponding to the rotation amount of the cam ring 207.
[0057]
Further, since the first lens piece 208 is engaged with the two grooves of the first front cam groove 207D1 and the first rear cam groove 207D2, it is always moved to a position corresponding to an intermediate position between these two grooves. For this reason, the error in the position of the first lens piece 208 in the axial direction is an intermediate value between the errors in the positions of the two grooves in the axial direction.
Similarly, since the second lens piece 209 is engaged with the two grooves of the second front cam groove 207E1 and the second rear cam groove 207E2, the second lens piece 209 is always moved to a position corresponding to an intermediate position between these two grooves. For this reason, the error in the position of the second lens piece 209 in the axial direction is an intermediate value between the errors in the position of the two grooves in the axial direction.
[0058]
That is, since the first and second lens pieces 208 and 209 take positions corresponding to the intermediate positions of the two cam grooves, the first and second lens pieces 208 and 209 are compared with the case where they are engaged with only one cam groove. Thus, the position error of the first and second lens pieces 208 and 209 is reduced. Accordingly, it is possible to improve the positional accuracy in the axial direction of the first and second lens pieces 208 and 209 with respect to the rotation amount of the cam ring 207.
[0059]
The presser plate 215 has a rectangular plate shape, is attached to the bottom wall of the cam ring 210 with a screw 810, and is provided so as to be movable integrally with the cam ring 210 in the front-rear direction.
A first lens interlocking plate 213 and a second lens interlocking plate 214 are disposed between the presser plate 215 and the bottom wall of the frame 101.
The first lens interlocking plate 213 is attached to the first lens piece 208 with a screw 811 and is configured to move integrally with the first lens piece 203.
The second lens interlocking plate 214 is attached to the second lens piece 209 with a screw 812, and is configured to move integrally with the second lens piece 209.
[0060]
The presser plate 215 has a rectangular plate shape and is provided with a hole 215B penetrating in the thickness direction. A screw 810 inserted through the hole 215B is screwed into the screw hole 210D2 of the connecting arm portion 210D of the cam frame 210. Attached to the cam frame 210. Therefore, the presser plate 215 is provided so as to be movable in the front-rear direction integrally with the moving shaft 206, the cam ring 207, and the cam frame 210.
A first lens interlocking plate 213 and a second lens interlocking plate 214 are disposed between the presser plate 215 and the bottom of the frame 101.
The first lens interlocking plate 213 is attached to a screw hole 208D1 provided in the mounting portion 208D of the first lens piece 208 with a screw 811 and is configured to move integrally with the first lens piece 203. .
The second lens interlocking plate 214 is attached to a screw hole 209D1 provided in the mounting portion 209D of the second lens piece 209 with a screw 812, and is configured to move integrally with the second lens piece 209. .
[0061]
As shown in FIG. 36, the first lens interlocking plate 213 has a rectangular plate-like first central portion 213A connected to the first lens piece 208 and the left and right edges of the first central portion 213A. The first arm portion 213 </ b> B is formed integrally with a first arm portion 213 </ b> B that extends in a straight line in the left-right direction after being bent toward the left.
The first central portion 213A is provided with a frame engaging portion 213C that engages with the mounting portion 208D of the first lens frame 208 and is attached by a screw 811.
Also, guided portions 213E and 213F made of ridges extending along the axis are provided at locations facing the lower side of the portion joined to the first central portion 213A of the right and left first arm portions 213B. ing. That is, the right and left first arm portions 213B extend rightward and leftward from the portions of the guided portions 213E and 213F.
The guided portions 213E and 213F are supported so as to be movable in the optical axis direction while being engaged with the guide portions 101C2 and 101D2 of the frame 101 described above.
[0062]
The first central portion 213A is supported so as to be movable in the front-rear direction with the lower surface and the upper surface in the thickness direction sandwiched between the presser plate 215 and the bottom of the frame 101, respectively.
Further, a concave groove 213D is formed in the right end portion and the left end portion of the first arm portion 213B along the extending direction of the arm. These two concave grooves 213D have right and left telescope optics described later. The first lens portions 307 and 407 of the system are configured to be engaged with each other while being movable in the left-right direction.
[0063]
As shown in FIG. 37, the second lens interlocking plate 214 has a rectangular plate-like second central portion 214A connected to the second lens piece 209 and the left and right edges of the second central portion 214A. The second arm portion 214B is formed integrally with the second arm portion 214B that extends in a straight line in the left-right direction after being bent.
The second central portion 214A is provided with an extending portion 214A1 extending forward from the second central portion 214A, and is engaged with the mounting portion 209D of the second lens piece 209 at a position near the front of the extending portion 214A1. A top engaging portion 214 </ b> C attached by a screw 812 is provided. The extending portion 214A has a rear portion on the lower surface thereof connected to the upper surface of the second central portion 214A, and the height direction positions of the lower surface of the extending portion 214A and the upper surface of the second central portion 214A are the same. Yes.
Also, guided portions 214E and 214F made of ridges extending along the axis are provided at locations facing the lower side of the portion joined to the second central portion 214A of the right and left second arm portions 214B. ing. That is, the right and left second arm portions 214B extend rightward and leftward from the locations of the guided portions 214E and 214F.
[0064]
The guided portions 214E and 214F are supported so as to be movable in the optical axis direction while being engaged with the guide portions 101C2 and 101D2 of the frame 101 described above.
The second central portion 214A is supported so as to be movable in the front-rear direction with the lower surface and the upper surface in the thickness direction sandwiched between the presser plate 215 and the bottom of the frame 101, respectively.
Further, a concave groove 214D is formed in the right end portion and the left end portion of the second arm portion 214B along the extending direction of the arm. These two concave grooves 214D have right and left telescope optical elements which will be described later. The second lens portions 308 and 408 of the system are configured to be engaged with each other while being movable in the left-right direction.
[0065]
The first and second lens interlocking plates 213 and 214 are sandwiched between the presser plate 215 and the bottom of the frame 101, the first lens interlocking plate 213 is in front of the optical axis direction, and the second lens interlocking plate 214 is light. It is located rearward in the axial direction, and is disposed in a state in which the extending portion 214A1 of the second central portion 214A is in contact with the upper surface of the first central portion 213A. In this state, the first and second arm portions 213D and 214D are positioned in the same height in the height direction of the first and second central portions 213A and 214A. It is comprised so that a position may become substantially the same.
[0066]
Further, a hole portion 215A penetrating in the left-right direction is formed at a position closer to the front of the presser plate 215, and the lens body interlocking shaft 216 is inserted into the hole portion 215A, and the right and left side portions of the presser plate 215 are provided. The holding plate 215 is held in a state of extending outward from the left and right edges.
The right moving body 303 and the left moving body 403 that hold the right and left eyepiece portions described later are engaged with the mirror interlocking shaft 216 so as to be movable in the axial direction thereof. 403 </ b> A <b> 1 is provided, and the right moving body 303 and the left moving body 403 are supported so as to be movable in the left-right direction along the mirror interlocking shaft 216, and move in the front-rear direction integrally with the mirror interlocking shaft 216. It is configured as follows.
[0067]
The mirror interlocking shaft 216 held by the presser plate 215 is interposed between the first lens interlocking plate 213 and the second lens interlocking plate 214 disposed between the presser plate 215 and the bottom of the frame 101. It is provided to be located.
The first and second lens interlocking plates 213 and 214 are connected to the first and second lens pieces 208 and 209, respectively. The first and second lens pieces 208 and 209 are supported by the cam ring 207 and the cam frame 210. The cam ring 207 and the cam frame 210 are provided integrally with the presser plate 215 so as to be movable in the axial direction, that is, in the optical axis direction. Therefore, the first and second lens interlocking plates 213 and 214 are moved integrally with the presser plate 215 in the optical axis direction during the focus adjustment operation described later.
[0068]
As shown in FIGS. 9, 10, and 18, the frame 101 supports the focus adjustment ring 202 rotatably and immovably in the axial direction in a state in which the focus adjustment ring 202 is accommodated. The housing portion 101G and the second housing portion 101H that supports the zoom adjustment ring 204 in a state of housing the zoom adjustment ring 204 so as to be rotatable and immovable in the axial direction are formed at intervals in the axial direction. .
The first accommodating portion 101G is configured to be sandwiched between the front wall portion 101G1 and the rear wall portion 101G2, and the second accommodating portion 101H is configured to be sandwiched between the wall portion 101G2 and the rear wall 101B of the frame 101. .
[0069]
According to the above configuration, when the zoom adjustment ring 204 is rotated without the focus adjustment ring 202 being rotated, the main shaft 201 fixed to the zoom adjustment ring 204 is rotated. Then, the cam ring 207 fixed to the front end of the main shaft 201 is rotated inside the cam frame 210.
Accordingly, the first and second cam grooves 207D and 207E formed on the outer peripheral surface of the cam ring 207 rotate with respect to the cam frame 210. Then, the first lens piece 208 and the second lens piece 209 engaged with each sphere 210B are guided by the shafts 211 and 212 in conjunction with the rotation of the first and second cam grooves 207D and 207E, respectively, and the axis of the main shaft 201 is reached. It is moved along the direction. At this time, as described above, the first lens piece 208 and the second lens piece 209 move in the opposite direction along the axial direction, that is, the optical axis direction.
[0070]
On the other hand, when the focus adjustment ring 202 is rotated without rotating the zoom adjustment ring 204, the main shaft 201 is not rotated and only the focus adjustment ring 202 is rotated. Then, the sphere 203 engaged with the main body 202 </ b> A of the focus adjustment ring 202 is not moved in the axial direction of the main shaft 201, but rotates around the axis while being engaged with the guide groove 206 </ b> A <b> 1 of the moving shaft 206. As a result, the moving shaft 206 and the cam frame 210 fixed integrally therewith are moved along the axial direction of the main shaft 201 inside the frame 101.
As described above, the guide groove 206A1 includes the first groove part 206A11 having a wide pitch and the second groove part 206A12 connected to the first groove part 206A11 and having a narrow pitch.
Therefore, in the state where the sphere 204B is moving in the range of the first groove 206A21 and the state in which the sphere 204B is moving in the range of the second groove 206A12, the moving shaft 206 and the cam for the same rotation angle of the focus adjustment ring 202 The amount of movement of the frame 210 is such that the former is larger than the latter. This is because a part of the mirror body is quickly retracted in the former range, and the distance of the eyepiece to the objective lens is finely adjusted, that is, the focus is finely adjusted in the latter range.
[0071]
Next, the configuration of the right mirror body 300 and the left mirror body 400 will be described.
In addition, each part which comprises the right mirror 300 and the left mirror 400 differs in the point that the shape is mainly comprised symmetrically, and is often functionally the same. Therefore, in the following description, except for parts having different functions on the left and right, the parts on the right mirror side will be described so as to explain the parts on the left mirror side.
In addition, as will be described below, the right mirror part is numbered in the 300s and the left mirror part is numbered in the 400s, and the parts constituting the right and left mirrors correspond to each other. Commonly attach the last two digits of the parts and alphabetic characters.
[0072]
As shown in FIG. 5, the right mirror 300 includes a right frame 301, a right frame lid 302, a right moving body 303, a right eyepiece 304, a right objective unit 305, a prism unit 306, a first lens unit 307, A second lens unit 308, an eyepiece unit 309, a right exterior unit 310, and the like are provided.
First, the configuration of the right mirror 300 will be schematically described. The right frame 301, the right frame lid 302 attached to the right frame 301, the right objective unit 305, and the right exterior unit 310 include the right interlock plate 109 ( 7) and is configured to be movable in the left-right direction together with the right interlocking plate 109.
[0073]
The right moving body 303 is provided so as to be slidable in the front-rear direction with respect to the right frame 301. A prism portion 306 is attached to the front of the right moving body 303, a right eyepiece 304 is attached to the rear of the right moving body 303, and an eyepiece 309 is attached to the rear of the right eyepiece 304. ing. Furthermore, a first lens unit 307 and a second lens unit 308 are provided between the right moving body 304 and the right eyepiece 304 so as to be slidable in the front-rear direction.
That is, among the objective unit 305, the prism unit 306, the first lens unit 307, the second lens unit 308, and the eyepiece unit 309 constituting the right telescope optical system, the objective unit 305 is attached to the right frame 301, The prism unit 306, the first lens unit 307, the second lens unit 308, and the eyepiece unit 309 are attached to the right moving body 303.
Accordingly, when the right moving body 303 slides in the front-rear direction with respect to the right frame 301, the objective unit 305, the prism unit 306, the first lens unit 307, the second lens unit 308, and the eyepiece unit 309 are interposed. , That is, the focal length is adjusted.
That is, the right moving body 304 and the right eyepiece tube 304 constitute a lens holding portion for holding the objective lens or the eyepiece lens in the present invention, and similarly, the left moving body 404 and the left eyepiece tube 404 described later in the present invention. A lens holding unit is configured. In addition, first and second lenses 307B and 308C, which will be described later, constituting the eyepiece lens, and first and second lenses 407B and 408C are respectively connected to the holding plate 215 and the lens body connecting shaft 216 via these lens holding portions. It will be connected.
[0074]
Next, the configuration of the right mirror 300 will be described in more detail with reference to FIGS. 8 and 12 to 14.
The right frame 301 is provided with a holding portion 301B for holding the rear portion of the right guide shaft 301A at an intermediate position in the height direction on the right side of the rear portion, and the right frame 301 is attached to the right interlocking plate 109 below the holding portion 301B. A screw hole 301C into which a screw to be attached is screwed is provided (see arrow B).
The attachment of the right frame 301 to the right interlocking plate 109 will be described in detail with reference to FIG.
Screws 820 and 820 are screw holes (not shown) provided in the rear portion of the right frame 301 through elongated holes 102H1 and 102H2 of the support plate 102 and screw insertion holes 109C1 and 109C2 of the right interlocking plate 109, and a frame lid 302 described later. Are screwed into the screw holes (not shown). At this time, the heads of the screws 820 and 820 are configured so as to be able to move in the left-right direction without interfering with the edges of the long holes while being positioned in the long holes 102H1 and 102H2 of the support plate 102. ing.
The screws 821 and 821 are screwed into the front and rear screw holes (the front screw holes correspond to the screw holes 301C) provided in the right frame 301 through the screw insertion holes 109D1 and 109D2 of the right moving body 109. . At this time, the heads of the screws 821 and 821 can move to positions in the notches 102J1 and 102J2 of the support plate 102, and can move in the left-right direction without interfering with the edges of these notches. It is comprised so that.
Thus, the right frame 301 is attached to the right interlocking plate 109 by the screws 820 and 821.
[0075]
In addition, since the attachment to the left interlocking | linkage board 110 of the left frame 401 (refer FIG. 15) mentioned later is the same as that of the above, it demonstrates here.
That is, the screws 822 and 822 are screw holes (not shown) provided in the rear portion of the left frame 401 described later through the long holes 102I1 and 102I2 of the support plate 102 and the screw insertion holes 110C1 and 110C2 of the left interlocking plate 110, respectively. The frame lid 402 is screwed into a screw hole (not shown). At this time, the heads of the screws 822 and 822 are positioned in the long holes 102I1 and 102I2 of the support plate 102, and can be moved in the left-right direction without interfering with the edges of the long holes. Has been.
Further, the screws 823 and 823 are screwed into front and rear screw holes (not shown) provided in the left frame 401 via screw insertion holes 110D1 and 110D2 of the left interlocking plate 110. At this time, the heads of the screws 823 and 823 can move to positions in the notches 102K1 and 102K2 of the support plate 102, and can move in the left and right directions without interfering with the edges of these notches. It is comprised so that.
As described above, the left frame 401 is attached to the left interlocking plate 110 by the screws 822 and 823.
[0076]
Returning to the description of the configuration of the right mirror 300.
The right frame 301 is provided with a holding portion 301E that holds the rear portion of the left guide shaft 301D at an intermediate position in the height direction on the left side of the rear portion (see arrow A).
A screw hole 301F is provided at an intermediate position in the height direction of the right wall near the front of the right frame 301. Between the head of the screw 814 screwed into the screw hole 301F and the right wall. The guide shaft 301A is held by sandwiching the front portion of the guide shaft 301A.
[0077]
A screw hole 301 </ b> G is provided in the upper right portion of the front wall portion of the right frame 301. Then, the screw 814 is screwed into the screw hole 301 </ b> G through the screw insertion hole 302 </ b> A of the right frame cover 302, so that the right frame cover 302 is attached to the front portion of the right frame 301. The front portion of the guide shaft 301D is held by the right frame lid 302.
Further, a screw hole 302B is provided in the front portion of the right frame lid 302, and the screw 815 is screwed into the screw hole 302B via a screw insertion hole 310A22 provided in the front wall 310A2 of the right exterior 310A. Thus, the front part of the right frame 301 and the front wall 310A2 of the right exterior 310A are fixed via the right frame cover 302.
[0078]
Further, the screw 816 is screwed into a position above the screw hole 301F of the right frame 301 via the screw insertion hole 310A41 provided in the right side wall 310A4 of the right exterior 310A, so that the right side of the right frame 301 and the right exterior The right side wall 310A4 of 310A is fixed.
Further, a screw hole 301H is provided in the left side wall of the rear part of the right frame 301, and the screw 817 is screwed into the screw hole 301H via a screw insertion hole 310A32 provided in the rear wall 310A3 of the right exterior 310A. By doing so, the rear part of the right frame 301 and the rear wall 310A3 of the right exterior 310A are fixed.
Further, a hole 301J facing rearward is provided in the rear left wall of the right frame 301 so that a fitting convex portion 310C2 of the right rear cover 310C described below is fitted into the hole 301J. It has become.
[0079]
The right exterior part 310 includes a right exterior 310A, a right front cover 310B, a right rear cover 310C, and the like.
The right exterior 310A includes a bottom wall 310A1, a front wall 310A2, a rear wall 310A3, a right wall 310A4, and a front wall 310A2, a rear wall 310A3, and a right wall 310A4 that are erected from the front and rear and right edges of the bottom wall 310A. It is comprised from the upper wall 310A5 which connects an upper part.
[0080]
The front wall 310A2 is formed with an opening 310A21 for allowing an objective lens 305C, which will be described later, to face outward, and the rear wall 310A3 is provided for causing a third lens 309C of eyepieces, which will be described later, to face outward. An opening 310A31 is formed.
A concave notch 310A51 for allowing the above-described focus adjustment ring 202 and zoom adjustment ring 204 to face outward is formed at a position near the rear of the right edge of the upper wall 310A5.
The right front cover 310B is attached to the front side of the front wall 310A2 by a double-sided tape 310D with the opening 310B1 aligned with the opening 310A21.
[0081]
Further, the right rear cover 310C is attached to the rear surface side of the rear wall 310A3 by the double-sided tape 310E in a state where the opening 310C1 coincides with the opening 310A31.
As shown in FIGS. 5 and 12, the rear wall 310A3 of the right exterior 310A is provided with a through hole 310A33 at a position corresponding to the hole 301J of the right frame 301, and the right rear cover 310C. The fitting projection 310C2 is fitted into the hole 301J of the right frame 310 through the through hole 310A33, so that the right rear cover 310C is positioned with respect to the right frame 310 and the right exterior 310A. ing.
Further, a semicircular recess 310A11 is formed at a position near the front of the left edge of the bottom wall 310A1 of the right exterior 310A. The recess 310A11 is provided so that the diopter difference decorative ring 106 and the bottom wall 310A1 do not interfere with each other.
[0082]
The objective unit 305 includes a right objective frame 305A, an objective presser ring 305B, an objective lens 305C, and the like.
The right objective frame 305A includes a cylindrical wall-shaped main body 305A1, a first holding portion 305A2 provided on the right side of the main body 305A1, and a second holding portion 305A3 extending rearward from the left side of the main body 305A1. Equivalent to the left guide shaft holding portion) and an engaging portion 305A4 extending leftward from the front portion of the second holding portion 305A3.
The inner peripheral portion of the main body 305A1 is configured to hold the outer peripheral edge portion of the objective lens 305C, and a male screw formed on the outer peripheral portion of the objective presser ring 305B is screwed to a female screw formed on the inner peripheral portion. The objective lens 305C is held by the main body 305A1 and the objective presser ring 305B.
[0083]
The first holding portion 305A2 is provided so as to be movable in the axial direction of the guide shaft 301A while holding the above-described guide shaft 301A.
A bearing hole 305A31 is provided in the second holding portion 305A3 with its axis oriented in the front-rear direction, and a guide shaft 301D is inserted through the bearing hole 305A31. The second holding portion 305A3 is provided so as to be movable in the axial direction of the guide shaft 301D while holding the guide shaft 301D.
For this reason, the objective frame 305A is configured to be movable in the front-rear direction along the guide shafts 301A and 301D.
Therefore, the objective lens 305C held by the right objective frame 305A is configured such that the position in the optical axis direction with respect to the right frame 301 can be set to an arbitrary position in the axial direction of the guide shafts 301A and 301D. Yes.
[0084]
The engaging portion 305A4 has a rectangular plate shape, and the engaging wall portion 305A41 is erected from the front edge and the rear edge downward. These two engagement wall portions 305A41 are provided to extend in the left-right direction in a state of being parallel to each other with a space therebetween. Further, the outer peripheral surface of the diopter difference eccentric seat 107 is provided between the two engagement wall portions 305A41, and when the diopter difference eccentric seat 107 is rotated, the view is rotated eccentrically. Each engagement wall portion 305A41 comes into contact with the outer peripheral surface of the degree-difference eccentric seat 107 and is moved in the front-rear direction.
That is, when the diopter difference eccentric seat 107 is rotated, the right objective frame 305A is moved back and forth along the axial direction of the guide shafts 301A and 301D, that is, the optical axis direction, integrally with the guide shafts 301A and 301D. It is like that.
[0085]
The right moving body 303 includes a rectangular bottom wall 303A, a rear wall 303B raised from the rear edge of the bottom wall 303A, and a side wall 303C raised from the left edge of the bottom wall 303A.
An engaging portion 303A1 extending in the left-right direction is provided at a substantially center in the front-rear direction of the left edge of the bottom wall 303A. The engaging portion 303A1 is in the axial direction with respect to the lens body interlocking shaft 216 described above. Is movably engaged.
The rear wall 303B is provided with a circular hole 303B1 at the center thereof. A bearing portion 303D through which the guide shaft 301A is inserted is provided at the right edge portion of the bottom wall 303A, and a bearing portion 303E through which the guide shaft 301D is inserted is provided at the lower portion of the side wall 303B.
Therefore, the right moving body 303 is held so as to be movable in the front-rear direction by the bearing portions 303D and 303E being guided by the guide shafts 301A and 301D, respectively.
[0086]
The prism unit 306 includes a holder 306A, an intermediate plate 306B, a holder lid 306C, a fine movement plate 306D, a first prism 306E, a second prism (dach prism) 306F, and the like.
The holder 306A includes an upper wall 306A1 and a bottom wall 306A2 that hold the upper and bottom surfaces of the first prism 306E and the second prism 306F, and a rectangular rear wall 306A3 that connects the rear edges of the upper wall 306A1 and the bottom wall 306A2. It is prepared for.
[0087]
The first prism 306E and the second prism 306F constituting the erecting prism are configured so that light rays pass in this order, and between the exit surface of the first prism 306E and the entrance surface of the second prism 306F. In a state where the intermediate plate 306B is disposed, the holder 306A is bonded and fixed to the upper wall 306A1 and the bottom wall 306A2.
The holder lid 306C has right and left side walls 306C2 erected rearward from the left and right edges of the front wall 306C1 and the front wall so as to connect the front and side edges of the upper wall 306A1 and the bottom wall 306A2 of the holder 306A. , 306C3, and an opening 306C11 through which light passes is provided in the front wall 306C1 facing the incident surface of the first prism 306E.
[0088]
The rear wall 306A3 of the holder 306A is also provided with an opening through which light emitted from the second prism 306F passes.
A fine movement plate 306D is arranged between the rear surface of the rear wall 306A3 of the holder 306A and the rear wall 303B of the moving body 303, and an opening 306D1 through which light passes is provided at the center.
Screw holes 306A31 are formed in the rear wall 306A3 of the holder 306A so as to face rearward at two locations across the opening. Two screws 815 are attached to the rear of the holder 306A via a screw insertion hole 303B2 provided in the rear wall 303B of the moving body 303 and a screw insertion hole 306D2 provided in the fine movement plate 306D via spring washers 816 and washers 817. The holder 306A is integrally fixed to the moving body 303 by being screwed into two screw holes of the wall 306A3.
[0089]
In addition, projecting pieces 303B3 extend rearward from the upper edge, left edge, and lower edge of the rear wall 303B of the moving body 303, and screw holes 303B31 are formed in the thickness direction of these projecting pieces 303B3. Is formed.
The right eyepiece 304 includes a bottom wall 304A, a right side wall 304B, a left side wall 304C, and a rear wall 304D that are erected from the right edge, the left edge, and the rear edge of the bottom wall 304A, and the right side wall 304B, the left side wall 304C, The upper wall 304E connects the upper part of the rear wall 304D.
The front edge portions of the bottom wall 304A, the right wall 304B, the left wall 304C, and the upper wall 304E are configured so that the rear wall 303B of the moving body 303 is fitted to the bottom wall 304A, the right wall 304B, and the upper wall. Screw insertion holes 304F are provided at locations near the front edge of 304E. The three screws 818 are screwed into the screw holes 303B31 formed in the protrusions 303B3 of the rear wall 303B via the screw insertion holes 304F, so that the rear wall 303B of the moving body 303 is fixed to the right eyepiece 304. It has come to be.
Therefore, the right eyepiece 304 and the prism unit 306 are integrally fixed to the moving body 303, and the right eyepiece 304, the prism unit 306, and the moving body 303 are guided with respect to the right frame 301 and the objective unit 305. It is provided to be movable in the optical axis direction along the axes 301A and 301D.
[0090]
Between the rear surface of the rear wall 303B of the moving body 303 and the front surface of the rear wall 304D of the right eyepiece tube 304, two guide shafts 311 that are parallel to each other extend along the front-rear direction, that is, the optical axis direction. It is provided in the state.
The first lens unit 307 includes a first lens frame 307A and a first lens 307B.
The first lens frame 307A includes a cylindrical wall-shaped main body 307A1, an engaging arm 307A2 extending forward from the lower edge of the main body 307A1, and a right edge and a left edge of the main body 307A1 extending rearward. The bearing arm portions 307A3 and 307A4 are provided.
[0091]
The outer peripheral edge portion of the first lens 307B is held on the inner peripheral portion of the main body 307A1 of the first lens frame 307A.
A portion of the engaging arm portion 307A2 facing the support plate 101, that is, a lower end of the engaging arm portion 307A2, has a concave groove 213D provided in the first arm portion 213B on the right side of the first lens interlocking plate 213 described above. An engaging convex portion 307A21 to be engaged is provided. The engagement convex portion 307A21 is configured to be immovable in the front-rear direction while being engaged with the concave groove 213D and movable in the left-right direction (the length direction of the first arm portion 213B). . That is, the first lens interlocking plate 213 and the first lens 307B are connected via the first lens frame 307A.
Bearing holes 307A31 and 307A32 through which the guide shaft 311 is inserted are provided before and after the bearing arm portion 307A3 of the main body 307A1. The bearing arm 307A4 is provided with a bearing hole 307A41 through which the guide shaft 311 is inserted.
Therefore, the main body 307A1 is held so as to be movable in the front-rear direction with respect to each guide shaft 311 by three locations of bearing holes 307A31, 307A32, and 307A41 through which each guide shaft 311 is inserted.
[0092]
The second lens unit 308 includes a second lens frame 308A, a second lens pressing ring 308B, and a second lens 308C.
The second lens frame 308A includes a cylindrical wall-shaped main body 308A1, an engaging arm 308A2 extending forward from the lower edge of the main body 308A1, a bearing 308A3 provided on the right edge of the main body 308A1, It is comprised from bearing part 308A4 provided in the left edge part of main body 308A1.
The inner peripheral part of the main body 308A1 of the second lens frame 308A is configured to hold the outer peripheral part of the second lens 308C, and is formed on the outer peripheral part of the second lens pressing ring 308B on the female screw formed on the inner peripheral part. The second lens 308C is held by the main body 308A1 and the second lens pressing ring 308B by screwing the formed male screw.
[0093]
At the position facing the support plate 101 of the engagement arm 308A2, that is, at the lower end of the front end of the engagement arm 308A2, a concave groove 214D provided in the second arm 214B on the right side of the second lens interlocking plate 214 described above. An engaging convex portion 308A21 to be engaged is provided. The engaging convex portion 308A21 is configured to be immovable in the front-rear direction while being engaged with the concave groove 214D and movable in the left-right direction (the length direction of the second arm portion 214B). .
The bearing portion 308A3 of the main body 308A1 is provided with a bearing hole 308A31 through which the guide shaft 311 is inserted. In addition, bearing holes 308A41 and 308A42 through which the guide shaft 311 is inserted are provided in the bearing portion 308A4 with a space in the front-rear direction.
Accordingly, the main body 308A1 is held so as to be movable in the front-rear direction with respect to the respective guide shafts 311 by the three portions of the bearing portions 308A31, 308A41, and 308A42 through which the respective guide shafts 311 are inserted.
[0094]
The eyepiece unit 309 includes an eyepiece lens frame 309A, an eyepiece lens holding ring 309B, a third lens 309C, and an eyepiece 309D.
The inner peripheral portion of the eyepiece frame 309A is configured to hold the outer peripheral portion of the third lens 309C, and the male screw 309B1 formed on the outer peripheral portion of the eyepiece holding ring 309B is connected to the female screw 309A1 formed on the inner peripheral portion. The third lens 309C is held by the eyepiece lens frame 309A and the eyepiece lens holding ring 309B.
A hole penetrating in the thickness direction of the rear wall 304D is formed in the rear wall 304D of the right eyepiece tube 304, and a mounting portion 304D1 is provided by forming an internal thread in the inner peripheral portion of the hole. Then, the male screw 309A2 formed on the outer peripheral portion of the eyepiece lens frame 309A is screwed to the female screw of the attachment portion 304D1, so that the eyepiece lens frame 309A is attached to the attachment portion 304D1.
[0095]
On the upper surface of the bottom wall 304A of the right eyepiece 304, a clearance groove 304A1 is formed extending in the front-rear direction to allow the movement of the portion of the first lens frame 307A closer to the rear of the engaging arm 307A2 in the front-rear direction. ing. Further, a clearance groove 304A2 that allows the movement of the portion of the second lens frame 308A near the rear of the engagement arm portion 308A2 in the front-rear direction is formed to extend in the front-rear direction on the left side of the clearance groove 304A1.
[0096]
Further, the front portion of the engagement arm portion 307A2 of the first lens frame 307A and the front portion of the engagement arm portion 308A2 of the second lens frame 308A are the front edge of the bottom wall 304A of the right eyepiece tube 304. It extends from the front.
On the lower surface of the bottom wall 303A of the moving body 303, a guide groove 303A2 (see FIGS. 38 and 39) for guiding a front portion of the engaging arm portion 307A2 of the first lens frame 307A in the front-rear direction is provided. And a guide groove 303A3 (see FIGS. 38 and 39) for guiding a portion closer to the front of the engaging arm 308A2 of the second lens frame 308A in the front-rear direction. Is formed.
[0097]
Therefore, the engaging arm portion 307A2 of the first lens frame 307A and the engaging arm portion 308A2 of the second lens frame 308A are held by the moving body 303 and the right eyepiece 304 so as to be movable in the front-rear direction.
By moving the first lens frame 307A and the second lens frame 308A toward or away from each other, the objective lens 305C, the prism unit 306, the first lens 307, the second lens 308, and the third lens 309 are moved. The magnification of the configured telescope optical system is configured to be changed.
That is, in this telescope optical system, the objective lens is constituted by the objective lens 305C, and the eyepiece lens is constituted by the first lens 307, the second lens 308, and the third lens 309.
Then, the magnification of the telescope optical system is changed by moving the first lens 307 and the second lens 308 of the eyepiece lenses in the direction of moving toward and away from each other in the optical axis direction.
[0098]
Next, the left objective frame 405 </ b> A having a configuration different from the elements configuring the right mirror 300 among the elements configuring the left mirror 400 will be described.
As shown in FIG. 16, the left objective frame 405A extends rearward from the cylindrical wall-shaped main body 405A1, the first holding portion 405A2 provided on the left side of the main body 305A1, and the right side of the main body 405A1. The second holding unit 305A3.
The inner peripheral part of the main body 405A1 is configured to hold the outer peripheral edge part of the objective lens 405C, and the male screw formed on the outer peripheral part of the objective presser ring 405B is screwed to the female screw formed on the inner peripheral part. The objective lens 405C is held by the main body 405A1 and the objective pressing ring 405B.
[0099]
The first holding portion 405A2 is configured to hold the guide shaft 401A so as to be movable in the axial direction thereof.
The second holding portion 405A3 (corresponding to the right guide shaft holding portion in the claims) is provided with a bearing hole 405A31 with its axis oriented in the front-rear direction, and a guide shaft 401D (claims) in the bearing hole 405A31. Is equivalent to the right guide shaft). The second holding unit 405A3 is configured to hold the guide shaft 401A so as to be movable in the axial direction thereof.
For this reason, the objective frame 405A is held so as to be movable in the front-rear direction along the guide shafts 401A and 401D. The right objective frame 405A is fixed to the guide shaft 301A by a screw 819 that is screwed into the first holding portion 405A2.
[0100]
Therefore, the objective lens 405C held by the left objective frame 405A can be set at an arbitrary position along the axial direction of the guide shafts 401A and 401D with respect to the left frame 401 in the optical axis direction position. It is configured to be fixed at the set position by a screw 819 screwed into the portion 405A2.
That is, the left objective frame 405A is not provided with a configuration corresponding to the engaging portion 305A4 that engages with the diopter difference eccentric seat 107 in the right objective frame 305A. Therefore, the position of the objective lens 405C in the optical axis direction with respect to the left frame 401 is fixed by screwing the screw 819 into the first holding portion 405A2 in the manufacturing process, and the user cannot adjust it after the product is completed. It has become.
On the other hand, the position of the right lens body 300 in the optical axis direction with respect to the right frame 301 of the objective lens 305C is adjusted as described above by rotating the diopter difference decorative ring 106, that is, the diopter difference eccentric seat 107. It is configured to be able to.
That is, the diopter difference adjusting ring 106, the diopter difference eccentric seat 107, and the left objective frame 305A constitute a diopter difference adjusting mechanism.
[0101]
Next, an operation when using the binoculars 1000 configured as described above will be described.
First, as shown in FIGS. 1 and 2, the right eyepiece tube 304 and the left eyepiece tube 404 are accommodated in the exterior in a state where the right mirror 300 and the left lens body 400 of the binoculars 1000 are closed, that is, It shall be in the retracted state.
The user supports the right mirror 300 with the right hand and the left mirror 400 with the left hand. At this time, the right and left thumbs hold the lower surface of the bottom wall of the right exterior and the left exterior, and the other fingers of the right hand and the left hand hold the upper surface of the upper wall of the right exterior and the left exterior from below and above, respectively. Become.
[0102]
Here, since the focus adjustment ring 202 and the zoom adjustment ring 204 are disposed adjacent to the main shaft 201 provided on the center line in the horizontal direction of the binoculars 1000, that is, adjacent to the same axis, either the right hand or the left hand When the focus adjustment ring 202 and the zoom adjustment ring 204 are rotated by the index finger or the middle finger, there is an advantage that the rotation operation can be easily performed with either the right hand or the left hand.
Then, when the focus adjustment ring 202 is rotated in a predetermined direction by a finger, the arm 202A1 extending in the axial direction integrally with the main body 202A is rotated and engaged with the hole-shaped engaging portion 202A11 of the arm 202A1. The spherical body 203 moves along a guide groove 206A1 formed in a double thread shape on the first shaft portion 206A of the moving shaft 206.
Convex portions 206C4 and 206C5 provided on the right and left sides of the flange portion 206C of the moving shaft 206 are along guide groove portions 101C11 and 101D11 provided to extend in the front-rear direction on the right wall 101C and the left wall 101D of the frame 101. Moved. The front portions of the moving shaft 206 are regulated by the convex portions 206C4 and 206C5 coming into contact with the step portions 101C12 and 101D12, and the rear portions by making the convex portions 206C4 and 206C5 come into contact with the rear wall portion 101G1 of the frame 101. Side position is regulated.
In the range in which the sphere 203 moves along the first groove 206A11 having a large pitch, the movement amount of the moving shaft 206 is large with respect to the rotation amount of the focus adjusting ring 202, and the sphere 203 has a second groove 206A12 having a narrow pitch. In the range in which the movement is performed, the movement amount of the moving shaft 206 is smaller than the rotation amount of the focus adjustment ring 202.
[0103]
A holding plate 215 is integrally attached to the moving shaft 206 to which the cam frame 210 is attached, and a moving body interlocking shaft 216 is integrally attached to the holding plate 215. Therefore, the right moving body 306 and the left moving body 406 are moved backward in conjunction with the movement of the moving shaft 206.
As a result, the right eyepiece tube 304 and the left eyepiece tube 404 are projected from the rear of the binoculars 1000.
In this state, the right eyepiece 300 and the left eyepiece 400 are opened in the left-right direction so that the right and left fields of view overlap each other while looking at a distant object while looking through the eyepieces 309 and 409 with both eyes. Adjust the eye width with.
As described above, the right exterior 310A and the left exterior 410A are fixed to the right interlocking plate 109 and the left interlocking plate 110, respectively. Accordingly, the right mirror 300 and the left mirror 400 move in conjunction with a direction approaching or separating along the left-right direction, and are the same distance in the left-right direction with respect to the center of the binoculars 1000 in the left-right direction. Since it moves, the eye width can be adjusted easily.
By applying a frictional force when the left interlocking plate 110 moves in the left-right direction, it is possible to improve the operational feeling during eye width adjustment.
[0104]
The focus adjustment is performed by rotating the focus adjustment ring 202. In other words, by rotating the focus adjustment ring 202, the integrally fixed right moving body 303, right eyepiece 304, and eyepiece 309 are moved in the optical axis direction with respect to the right objective frame 305A.
That is, the focus adjustment is performed by moving the prism unit 306, the first lens 307B, the second lens 308C, and the third lens 309C in a direction in which they are in contact with and away from the objective lens 305C.
Of course, the same focus adjustment operation is performed on the left mirror 400 at the same time.
[0105]
The magnification adjustment is performed by rotating the zoom adjustment ring 204. That is, by rotating the zoom adjustment ring 204, the main shaft 201 is rotated and the cam ring 207 is rotated with respect to the cam frame 210. Then, the first lens piece 208 and the second lens piece 209 engaged with the first cam groove 207D and the second cam groove 207E of the cam ring 207 via the sphere 210B are moved in the opposite directions.
As a result, the first lens interlocking plate 213 and the second lens interlocking plate 214 attached to the first lens top 208 and the second lens top 209 are engaged with the first lens interlocking plate 213 and the second lens interlocking plate 214. The first lens frame 307 </ b> A and the second lens frame 308 </ b> A are moved in a direction away from and approaching each other in conjunction with the first lens frame 208 and the second lens frame 209.
As shown in FIGS. 38 and 39, the first lens 307B and the second lens 308C are separated from each other and approach each other so that the objective lens 305C, the prism unit 306, the first lens 307B, the second lens 308C, and the third lens 307C are separated. The magnification of the telescope optical system constituted by the lens 309C is changed.
That is, as shown in FIG. 38 which is a plan view of the optical adjustment unit showing a state in which the telescope optical system is adjusted to the wide side, the telescope optics is in a state where the first lens 307B and the second lens 308C are most separated from each other. The system is adjusted to the wide side.
Further, as shown in FIG. 39 which is a plan view of the optical adjustment unit showing the state in which the telescope optical system is adjusted to the tele side, the telescope optical system is in a state where the first lens 307B and the second lens 308C are closest to each other. The system is adjusted to the tele side.
As described above, the first lens 307B and the second lens 308C are contacted and separated from each other, so that the telescope optical system configured by the objective lens 305C, the prism unit 306, the first lens 307B, the second lens 308C, and the third lens 309C is used. The magnification (zoom rate) is reduced or enlarged.
It goes without saying that the zoom adjustment operation is also performed at the same time in the left mirror 400 with the same configuration as the right mirror 300.
[0106]
Next, the diopter difference adjustment operation will be described.
First, the focus adjustment ring 202 is rotated with the left eye alone except for the third lens 409C of the left mirror 400, and the focus adjustment is performed so that a far object is in focus.
Next, the diopter difference decorative ring 106 is rotated with the right eye looking through the third lens 309C of the right mirror 300 so that the target is clearly visible.
That is, the diopter difference decorative ring 106 is rotated to rotate the diopter difference eccentric seat 107, and the position of the objective lens 305C in the optical axis direction with respect to the right frame 301 is adjusted to an arbitrary position, thereby reducing the diopter difference. Adjustments can be made.
If the user is the same, it is only necessary to adjust the focus after adjusting the diopter difference once.
Since the diopter difference decorative ring 106 is located at a position closer to the front side on the center line in the left-right direction of the support plate 102, it can be easily rotated with, for example, the thumb of either the left or right hand.
Further, since the diopter difference decorative ring 106 is provided at a position closer to the front side on the center line of the support plate 102, it is sufficiently separated from the position of the thumb when the focus adjustment or zoom adjustment is operated. Yes. For this reason, it is possible to prevent the diopter difference adjustment from being inadvertently caused by carelessly contacting the diopter difference decorative ring 106 with the thumb.
[0107]
In the present embodiment, the main shaft 201, the zoom adjustment ring 204, the cam ring 207, the first lens piece 208, the second lens piece 209, the cam frame 210, the piece guide shafts 211 and 212, and the first lens that constitute the optical adjustment unit 200. The interlocking plate 213 and the second lens interlocking plate 214 constitute a zoom adjusting mechanism as defined in the claims.
And according to this Embodiment, there exist the following effects.
Since the first and second lens pieces 208 and 209 receive a force from the cam ring 207 at two locations separated in the axial direction, the first and second lens pieces 208 and 209 are prevented from being inclined with respect to the axial direction by the force received from the cam ring 207. Shaking is prevented. Therefore, the first and second lens pieces 208 and 209 are accurately moved in the axial direction corresponding to the rotation amount of the cam ring 207.
As a result, the first and second lens interlocking plates 213 and 214 connected to the first and second lens pieces 208 and 209 are also accurately moved in the axial direction. Therefore, the first and second lens interlocking plates 213 and 214 are moved in the axial direction. The distance between the lenses between the second lenses 307B and 308C can be accurately adjusted, and the magnification of the image formed by the telescope optical system including the first and second lenses can be accurately adjusted. Has an effect.
[0108]
Further, as described above, since the first and second lens pieces 208 and 209 take positions corresponding to the intermediate positions of the two cam grooves, errors in the positions of the first and second lens pieces 208 and 209 are reduced. As a result, the positional accuracy of the first and second lens pieces 208 and 209 in the axial direction with respect to the rotation amount of the cam ring 207 can be improved, and the same operational effects as described above can be achieved.
[0109]
In the present embodiment, the first front engagement portion is constituted by the first front sphere holding portion 208A1, the first rear engagement portion is constituted by the first rear sphere holding portion 208A2, and the second front engagement portion. The second front sphere holder 209A1 and the second rear sphere holder 209A2 respectively, and the first and second lens pieces 208 and 209 and the first and second cam grooves 207D and 207E. Are configured to engage with each other via a sphere 210B. However, the present invention is not limited to the above configuration, and the first front engagement portion, the first rear engagement portion, the second front engagement portion, and the second rear engagement portion are respectively the first and second configurations. You may comprise by the engaging part of the shape which can be engaged with a cam groove.
In this embodiment, an example in which the zoom adjustment mechanism of the present invention is applied to binoculars has been described, but it goes without saying that the zoom adjustment mechanism of the present invention can be applied to optical devices other than binoculars.
[0110]
【The invention's effect】
The zoom adjustment mechanism of the present invention includes a cam member having a first cam groove and a second cam groove provided on the outer peripheral surface, a first connecting portion that is engaged with the first cam groove and connected to the first lens. And a second connecting portion engaged with the second cam groove and connected to the second lens, The first cam groove and the second cam groove are provided at different locations in the circumferential direction of the outer circumferential surface and in the same region of the outer circumferential surface in the axial direction. The first cam groove is composed of two grooves, a first front cam groove and a first rear cam groove, which are formed in the same shape and spaced apart in the axial direction, and the second cam groove has the same shape. The second front cam groove and the second rear cam groove are provided with a gap in the direction of the non-axial axis.
[0111]
Therefore, in the zoom adjustment mechanism of the present invention, the first connecting portion is engaged with the first front cam groove and the first rear cam groove spaced apart in the axial direction, and the second connecting portion is spaced in the axial direction. The second front cam groove and the second rear cam groove which are covered with each other are engaged with two places. As a result, the first and second connecting portions receive force from the cam member at two locations that are separated from each other in the axial direction.
Therefore, the force received by the first and second connecting portions from the cam member when the cam member is rotated as compared with the configuration in which the first and second connecting portions are respectively engaged with one place of the cam member. Thus, tilting with respect to the axial direction is suppressed, and rattling in the front-rear direction is prevented, so that the first and second connecting portions are accurately moved in the axial direction corresponding to the amount of rotation of the cam member.
As a result, the magnification of the image formed by the optical system including the first and second lenses is accurately adjusted by accurately adjusting the inter-lens distance between the first and second lenses according to the rotation amount of the cam member. Can be adjusted.
[0112]
Further, according to the zoom adjustment mechanism of the present invention, the first connecting portion is engaged with the two grooves of the first front cam groove and the first rear cam groove, and therefore always corresponds to the intermediate position between these two grooves. It is moved to the position. For this reason, the error in the position of the first connecting portion in the axial direction is an intermediate value of the error in the position of the two grooves in the axial direction.
Similarly, since the second connecting portion is engaged with the two grooves of the second front cam groove and the second rear cam groove, the second connecting portion is always moved to a position corresponding to an intermediate position between these two grooves. For this reason, the error in the position of the second connecting portion in the axial direction is an intermediate value between the errors in the positions of the two grooves in the axial direction.
That is, since the first and second connecting portions take a position corresponding to the intermediate position between the two cam grooves, the first and second connecting portions are compared with the case where only the first cam groove is engaged. 1. The error in the position of the second connecting portion is reduced. Accordingly, it is possible to improve the positional accuracy in the axial direction of the first and second connecting portions with respect to the rotation amount of the cam member.
As a result, the magnification of the image formed by the optical system including the first and second lenses is accurately adjusted by accurately adjusting the inter-lens distance between the first and second lenses according to the rotation amount of the cam member. Can be adjusted.
[Brief description of the drawings]
FIG. 1 is an external view showing a state in which a right eyepiece and a left eyepiece are closed and a right eyepiece and a left eyepiece are accommodated in an embodiment of a zoom adjustment mechanism of the present invention; FIG. FIG. 1B is a rear view showing the state of FIG. 1A viewed from the direction of the arrow A1, and FIG. 1C is a side view showing the state of FIG. 1A viewed from the direction of the arrow A2. It is.
2 is an external view of binoculars showing the same state as FIG. 1, FIG. 2 (A) is a bottom view, and FIG. 2 (B) is a rear view showing the state when FIG. 2 (A) is viewed from the direction of arrow A3. It is.
3 is an external view showing a state in which the right and left eyepieces are opened and the right eyepiece and the left eyepiece are most extended in the embodiment of the zoom adjustment mechanism of the present invention; FIG. ) Is a plan view, FIG. 3B is a front view of FIG. 3A viewed from the direction of arrow B1, FIG. 3C is a side view of FIG. 3A viewed from the direction of arrow B2, FIG. 3D is a side view of FIG. 3A viewed from the direction of arrow B3.
4 is an external view of binoculars showing the same state as FIG. 3, FIG. 4 (A) is a bottom view, and FIG. 4 (B) is a rear view showing the state when FIG. 4 (A) is viewed from the direction of arrow B4. FIG. 4C is a side view showing the state of FIG. 4A viewed from the arrow B5.
FIG. 5 is a partial cross-sectional view showing a state in which a part of binoculars is broken.
6 is a cross-sectional view taken along line XX of FIG.
FIG. 7 is an exploded perspective view showing an overall configuration of binoculars.
FIG. 8 is an exploded perspective view showing a part of the support portion.
FIG. 9 is an exploded perspective view showing a part of the support part and the optical adjustment part.
FIG. 10 is an exploded perspective view showing a configuration of an optical adjustment unit.
FIG. 11 is an exploded perspective view illustrating a configuration of a part of the optical adjustment unit and an upper plate.
FIG. 12 is an exploded perspective view mainly showing a configuration of a right exterior part of the right mirror body.
FIG. 13 is an exploded perspective view showing configurations of a right moving body, a right objective section, and a prism section of the right mirror body.
FIG. 14 is an exploded perspective view mainly showing a configuration of a first lens unit, a second lens unit, and an eyepiece unit of the right mirror body.
FIG. 15 is an exploded perspective view mainly showing a configuration of a left exterior part of the left mirror body.
FIG. 16 is an exploded perspective view showing the configuration of a left moving body, mainly a left moving body, a left objective section, and a prism section.
FIG. 17 is an exploded perspective view mainly showing a configuration of a first lens unit, a second lens unit, and an eyepiece unit of the left mirror body.
18A is a plan view of the main body, FIG. 18B is a cross-sectional view showing a state in which the main body is broken along the longitudinal direction, and FIG. C) is a bottom view of the main body.
19 is a cross-sectional view showing a state in which the main body is broken along a plane orthogonal to the longitudinal direction. FIG. 19 (A) is a cross-sectional view taken along line AA in FIG. 18 (B), and FIG. It is a BB line sectional view of).
20A and 20B are diagrams showing the configuration of the cam ring, in which FIG. 20A is a front view of the cam ring, FIG. 20B is a rear view of the cam ring, and FIG. 23C is FIG. D1D1 line sectional drawing, FIG.20 (D) is D2D2 line sectional drawing of FIG. 20 (A).
21A and 21B are diagrams showing the configuration of a cam groove provided on the outer periphery of the cam ring, FIG. 21A being a plan view and FIG. 21B being a development view of FIG. 21A.
FIG. 22 is a plan view of the cam frame.
FIG. 23 is a front view of the cam frame showing a state when FIG. 22 is viewed from the direction of arrow E1.
24 is a cross-sectional view taken along line E2E2 of FIG.
FIG. 25 is a rear view of the cam frame showing a state of FIG. 24 viewed from the direction of arrow E3.
FIG. 26 is a front view of a first lens piece.
FIG. 27 is a right side view of the first lens piece showing a state in which FIG. 26 is viewed from the direction of arrow F1.
FIG. 28 is a bottom view of the first lens piece showing a state in which FIG. 26 is viewed from the direction of arrow F2.
29 is a cross-sectional view taken along line F3F3 of FIG.
30 is a cross-sectional view taken along line F4F4 of FIG.
FIG. 31 is a front view of a second lens piece.
FIG. 32 is a left side view of the second lens piece showing the state of FIG. 31 viewed from the direction of arrow G1.
FIG. 33 is a bottom view of the second lens piece showing the state of FIG. 32 viewed from the direction of arrow G2.
34 is a cross-sectional view taken along line G3G3 of FIG.
35 is a cross-sectional view taken along line G4G4 of FIG.
36 is a diagram showing the configuration of the first lens interlocking plate, FIG. 36 (A) is a front view of the first interlocking plate, and FIG. 36 (B) is a state when FIG. 36 (A) is viewed from the arrow B. 36 (C) is a bottom view of the first interlocking plate showing the state of FIG. 36 (A) viewed from the arrow C, and FIG. 36 (D) is an arrow of FIG. 36 (B). It is a side view which shows the state seen from D.
37 is a diagram showing a configuration of a second lens interlocking plate, FIG. 37 (A) is a front view of the second interlocking plate, and FIG. 37 (B) is a state when FIG. 37 (A) is viewed from an arrow B. FIG. 37 (C) is a bottom view of the second interlocking plate showing the state of FIG. 37 (A) viewed from the arrow C. FIG.
FIG. 38 is a plan view of the optical adjustment unit showing a state in which the first and second lens interlocking plates are most separated and the telescope optical system is adjusted to the low magnification side.
FIG. 39 is a plan view of the optical adjustment unit showing a state in which the first and second lens interlocking plates are closest to each other and the telescope optical system is adjusted to the high magnification side.
[Explanation of symbols]
207 Cam ring
207D 1st cam groove
207D1 First front cam groove
207D2 First rear cam groove
207E Second cam groove
207E1 Second front cam groove
207E2 Second rear cam groove
208 1st lens piece
209 Second lens piece
214 First interlocking plate
215 Second interlocking plate
307B first lens
308C second lens

Claims (10)

In a zoom adjustment mechanism that adjusts the magnification of an image by changing the inter-lens distance between the first lens and the second lens arranged on the optical axis,
A cylindrical outer peripheral surface provided around the axis extending in parallel with the optical axis direction, and having a first cam groove and a second cam groove provided on the outer peripheral surface. A cam member;
A first connecting portion that is movable in the axial direction and non-rotatable in a direction around the axial line, is engaged with the first cam groove, and is connected to the first lens;
A second connecting portion that is movable in the axial direction and non-rotatable in the direction around the axial line, is engaged with the second cam groove, and is connected to the second lens;
The first cam groove and the second cam groove are provided at different locations in the circumferential direction of the outer circumferential surface and in the same region of the outer circumferential surface in the axial direction,
The first cam groove is composed of two grooves, a first front cam groove and a first rear cam groove, which have the same shape and are spaced apart from each other in the axial direction. It is composed of two grooves, a second front cam groove and a second rear cam groove, which have the same shape and are spaced apart in the axial direction.
A zoom adjustment mechanism characterized by that.   The first cam groove and the second cam groove are configured such that the first connecting portion and the second connecting portion move in opposite directions along the axial direction when the cam member rotates about the axis. The zoom adjustment mechanism according to claim 1, wherein the zoom adjustment mechanism is provided.   The first connecting portion engages with a first cam groove and moves along the axial direction when the cam member rotates, and a first frame connecting the first frame and the first lens. A second member that engages with a second cam groove and moves along the axial direction when the cam member rotates, the second member, and the second member; The zoom adjusting mechanism according to claim 1, further comprising a second connecting member that connects the lenses.   The first frame has a first front engagement portion that engages with the first front cam groove and a first rear engagement portion that engages with the first rear cam groove, and the first connecting portion and the first In the engagement of one cam groove, the first front engagement portion and the first rear engagement portion of the first frame engage with the first front cam groove and the first rear cam groove of the first cam groove, respectively. 4. The zoom adjustment mechanism according to claim 3, wherein the zoom adjustment mechanism is performed.   5. The zoom adjustment mechanism according to claim 4, wherein the first front engagement portion and the first rear engagement portion are provided so as to be positioned on the same straight line parallel to the axis. Each of the first front engagement portion and the first rear engagement portion includes a first front sphere holding portion and a first rear sphere holding portion that hold a sphere, and the first front engagement portion and the first front cam. The groove is engaged by the first front sphere holding portion engaging the first front cam groove via the sphere, and the first rear engagement portion and the first rear cam groove are engaged. 6. The zoom adjusting mechanism according to claim 4, wherein the first rear sphere holding portion is engaged with the first rear cam groove via the sphere.   The second frame has a second front engagement portion that engages with the second front cam groove and a second rear engagement portion that engages with the second rear cam groove, and the second connection portion and the second The two cam grooves are engaged in that the second front engaging portion and the second rear engaging portion of the second frame engage with the second front cam groove and the second rear cam groove of the second cam groove, respectively. The zoom adjustment mechanism according to claim 3, wherein the zoom adjustment mechanism is performed by performing the operation.   8. The zoom adjustment mechanism according to claim 7, wherein the second front engaging portion and the second rear engaging portion are provided so as to be positioned on the same straight line parallel to the axis. Each of the second front engagement portion and the second rear engagement portion includes a second front sphere holding portion and a second rear sphere holding portion that hold a sphere, and the second front engagement portion and the second front cam. The engagement of the groove is performed by the second front sphere holding portion engaging the second front cam groove via the sphere, and the engagement between the second rear engagement portion and the second rear cam groove. 9. The zoom adjustment mechanism according to claim 7, wherein the second rear sphere holding portion is engaged with the second rear cam groove via the sphere.   The zoom adjustment mechanism according to any one of claims 1 to 9, wherein the first and second lenses constitute an eyepiece lens or an objective lens included in a telescope optical system.

Images