JP2009080463A - Combined lens, lens unit, imaging apparatus, and optical equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combined lens which is capable of easily and highly accurately adjusting the relative position between lenses and to provide a lens unit using the combined lens, an imaging apparatus and optical equipment. <P>SOLUTION: The combined lens 10 includes a lens 11 and a lens 12. The lens 11 has a mortar-like conical surface 11a centering on an optical axis and a contact area 11b. The lens 12 has a curved surface 12a coming into contact with the conical surface 11a and a contact area 12b coming into contact with the contact area 11b. In the combined lens 10, a distance in the direction of the optical axis 13 between the lenses is adjusted to make tilt correctable by the contact of the conical surface 11a with the curved surface 12a and the tilt is adjusted by the contact area 11b with the contact area 12b. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a combination lens, and a lens unit, an imaging apparatus, and an optical apparatus using the combination lens.

  In recent years, a camera module mounted on a digital camera, a mobile phone, or the like has been required to have a high number of pixels, such as several million pixels. There is an increasing demand for reduction in thickness or weight.

  For this reason, it is necessary to reduce the size of the lens system used in the optical system of the camera module and to reduce the thickness of the housing of the camera module, and it is required to perform assembly adjustment of the optical system with a simple mechanism.

  The demand for size reduction is not limited to the camera module as described above, and similarly exists in general optical equipment using a plurality of lenses. In addition, since the demand for shortening the tact time in manufacturing is increasing, the demand for simplification of assembly adjustment is strong.

  Therefore, in order to meet such demands, a mechanism has been proposed in which, in an optical system composed of a plurality of lenses, the relative position between the lenses is adjusted only by fitting the lenses, and a high-precision optical system is easily realized. (Patent Document 1). If this portion for fitting can be realized in a small shape, a large adjustment mechanism can be eliminated.

FIG. 5 is a cross-sectional view showing an outline of the combination lens 100 described in Patent Document 1. As shown in FIG. As shown in FIG. 5, the combination lens 100 includes a lens 101 and a lens 102, and the conical surface 101a of the lens 101 and the conical surface 102a of the lens 102 are in surface contact. As a result, a clearance is provided between the opposing surfaces of the lens 101 and the lens 102 except for the conical surfaces 101a and 102a, and the distance in the optical axis direction between the lens 101 and the lens 102 is perpendicular to the optical axis. The relative position in the plane is determined simultaneously. Therefore, the lens 101 and the lens 102 can be assembled with high accuracy without adjusting from the outside.
JP 2002-286987 A (published on October 3, 2002)

  However, in the conventional combination lens, the relative position between the lenses cannot be easily adjusted with high accuracy. For this reason, it has been impossible to provide an optical device using such a combination lens.

  For example, as in the case of the combination lens 100 described in Patent Document 1, when positioning in the optical axis and the optical axis direction only by contact between the conical surfaces facing each other, the following problems occur. That is, as shown in FIG. 5, when the lens 101 and the lens 102 are combined, the lens 102 is inserted into the lens 101 unless the lens 102 is inserted along the direction of the optical axis 103 of the lens 101. May be assembled in a tilted state. As a result, both lenses are fitted with the optical axis 104 of the lens 102 slightly tilted with respect to the optical axis 103 of the lens 101, and the performance of the optical system is degraded.

  Therefore, it is necessary to insert the lens 102 with respect to the lens 101 with high accuracy. That is, when pressing the lens 102, it is necessary to apply a load to the lens 102 evenly along the direction of the optical axis 103, and a highly accurate assembly device is required.

  In addition, for example, in a combination lens configured to abut on a plane in addition to a conical surface, the lens is over-constrained, and an error that occurs when the conical surface abuts and an error that occurs when the plane abuts. Therefore, the lenses cannot be fitted with high accuracy.

  The present invention has been made in view of the above problems, and a combined lens capable of easily and accurately adjusting the relative position between lenses, and a lens unit, an imaging apparatus, and an optical apparatus using the combined lens The purpose is to provide.

  In order to solve the above-described problem, a combination lens according to the present invention is a combination lens including at least a first lens and a second lens, and the first lens includes a first contact region and a first curved surface. The second lens includes a second contact region and a second curved surface that contact the first contact region, and the first curved surface and the second curved surface are in contact within a specific plane. It is a feature.

  According to said structure, the distance of the optical axis direction between both lenses is prescribed | regulated by the 1st curved surface with which a 1st lens is provided, and the 2nd curved surface with which a 2nd lens is provided. Then, when the first contact region provided in the first lens and the second contact region provided in the second lens are in contact with each other, the inclination between the two lenses is defined, and the optical axes of both lenses can be aligned. . As described above, the combination lens according to the present invention can adjust the relative position between the lenses without the need for another adjustment mechanism by contacting the lenses.

  At this time, since the contact between the first curved surface and the second curved surface is limited to a specific plane, it cannot be a full surface contact and is close to a point contact, a line contact, or a point contact, or It becomes a state close to line contact. Therefore, the tilt between the two lenses is not completely defined by the contact. As a result, when the first lens and the second lens are fitted, the first contact area and the second contact area can be obtained even when the first lens and the second lens are combined in a slightly tilted state. The tilt is canceled by bringing the lens into contact with each other. Therefore, the first lens and the second lens can be easily fitted with high accuracy without a highly accurate assembly device.

  Furthermore, since the contact is a point contact, a line contact, a state close to a point contact, or a state close to a line contact, unlike the case of surface contact, it is not over-constrained and the lenses can be fitted with high accuracy. Can be done.

  As described above, the combination lens according to the present invention has an effect that the relative position between the lenses can be adjusted with high accuracy and easily by the contact of the lenses.

  In the combination lens according to the present invention, for example, the first curved surface is a mortar-shaped conical surface centered on the optical axis, and the second curved surface is formed of a spherical surface or an elliptical surface in contact with the conical surface. There may be. In other words, the combination lens according to the present invention is a combination lens including at least a first lens and a second lens, and the first lens is a mortar centered on the first contact region and the optical axis. The second lens has a second contact region that contacts the first contact region, and a curved surface that is a spherical surface or an elliptical surface that contacts the conical surface. It is a feature.

  According to said structure, the distance of the optical axis direction between both lenses is prescribed | regulated by the conical surface with which a 1st lens is provided, and the curved surface with which a 2nd lens is provided. Then, when the first contact region provided in the first lens and the second contact region provided in the second lens are in contact with each other, the inclination between the two lenses is defined, and the optical axes of both lenses can be aligned. . As described above, the combination lens according to the present invention can adjust the relative position between the lenses without the need for another adjustment mechanism by contacting the lenses.

  At this time, since the contact between the conical surface and the curved surface is a contact between the conical surface and the spherical surface or the elliptical surface, it cannot be a full surface contact and is in a line contact or a state close to a line contact. Therefore, the tilt between the two lenses is not completely defined by the contact. As a result, when the first lens and the second lens are fitted, the first contact area and the second contact area can be obtained even when the first lens and the second lens are combined in a slightly tilted state. The tilt is canceled by bringing the lens into contact with each other. Therefore, the first lens and the second lens can be easily fitted with high accuracy without a highly accurate assembly device.

  Furthermore, since the contact is a line contact or a state close to a line contact, unlike the case of the surface contact, it is not over-constrained and the lenses can be fitted with high accuracy.

  As described above, the combination lens according to the present invention has an effect that the relative position between the lenses can be adjusted with high accuracy and easily by the contact of the lenses.

  In the combination lens according to the present invention, for example, the first curved surface is a mortar-shaped conical surface centered on the optical axis, and the second curved surface is in line contact with the conical surface and the conical surface. May be. In other words, the combination lens according to the present invention is a combination lens including at least a first lens and a second lens, and the first lens is a mortar centered on the first contact region and the optical axis. The second lens may include a second contact region that contacts the first contact region, and a curved surface that makes line contact with the conical surface.

  According to said structure, the distance of the optical axis direction between both lenses is prescribed | regulated by the conical surface with which a 1st lens is provided, and the curved surface with which a 2nd lens is provided. Then, when the first contact region provided in the first lens and the second contact region provided in the second lens are in contact with each other, the inclination between the two lenses is defined, and the optical axes of both lenses can be aligned. . As described above, the combination lens according to the present invention can adjust the relative position between the lenses without the need for another adjustment mechanism by contacting the lenses.

  At this time, the contact between the conical surface and the curved surface is a line contact. Therefore, the tilt between the two lenses is not completely defined by the contact. As a result, when the first lens and the second lens are fitted, the first contact area and the second contact area can be obtained even when the first lens and the second lens are combined in a slightly tilted state. The tilt is canceled by bringing the lens into contact with each other. Therefore, the first lens and the second lens can be easily fitted with high accuracy without a highly accurate assembly device.

  Further, since the contact is a line contact, unlike the case of surface contact, it is not over-constrained and the lenses can be fitted with high accuracy.

  As described above, the combination lens according to the present invention has an effect that the relative position between the lenses can be adjusted with high accuracy and easily by the contact of the lenses.

  In the combination lens, both the first contact area and the conical surface are provided outside the optical effective range of the first lens, and both the second contact area and the curved surface are outside the optical effective range of the second lens. Is preferably provided.

  According to said structure, since the structure for aligning lenses is provided outside the optical effective range, the optical characteristic of a lens is not impaired.

  In the combination lens, in the first lens, the conical surface is provided at a position closer to the optical axis than the first contact region, and in the second lens, the curved surface is lighter than the second contact region. It may be provided at a position close to the axis.

  According to said structure, a 1st contact area | region and a 2nd contact area | region contact | abut on the outer side of the said conical surface and the said curved surface. Therefore, the outside of the conical surface of the first lens and the outside of the curved surface of the second lens can be effectively used.

  In the combination lens, in the first lens, the first contact region is provided at a position closer to the optical axis than the conical surface, and in the second lens, the second contact region is more than the curved surface. It may be provided at a position close to the optical axis.

  According to said structure, a 1st contact area | region and a 2nd contact area | region contact | abut inside the said conical surface and the said curved surface. Here, when the apex angle of the cone including the conical surface is small and the dimensions of the outer periphery of the conical surface of the first lens and the outer periphery of the curved surface of the second lens are small, the conical surface becomes thin and the cone When the curved surface comes into contact with the surface, the conical surface may be deformed, but even in that case, the inclination between the first contact region and the second contact region does not change. Both contact areas can be contacted satisfactorily.

  In the combination lens, it is preferable that a tangent plane of the curved surface and the conical surface coincide with each other at each point on a line where the curved surface and the conical surface abut.

  According to said structure, since the conical surface 11a and the curved surface 12a contact | abut in the position which has the same tangent plane, the deformation | transformation resulting from applicable contact does not arise. Therefore, there is no problem such as an increase in frictional force due to deformation, and it is possible to suppress an influence that inhibits the self-alignment action when the second lens is inserted into the first lens.

  Further, since the tangent planes of the conical surface 11a and the curved surface 12a coincide with each other, when the inclination is corrected, the conical surface 11a and the curved surface 12a relatively move along the tangent plane in a minute range. To do. Therefore, both lenses can be positioned smoothly.

  In the combination lens, it is preferable that the curved surface is a spherical surface centered on a point on the optical axis.

  According to the above configuration, since the curved surface is a spherical surface centered on a point on the optical axis, even if the second lens is inclined with respect to the first lens, it is centered on the point on the optical axis. Since the tilt is a simple rotational motion, the tilt can be corrected more easily.

  In the combination lens, the apex angle of a cone formed by rotating a straight line passing through the point where the conical surface and the curved surface come into contact with the center of the spherical surface around the optical axis is in the range of 60 degrees to 120 degrees. It is preferable to be within.

  The larger the apex angle is, the easier the correction of the inclination of the second lens with respect to the first lens is, and the accuracy of the jig or assembling device at the time of assembly is not required, but the relative position between the lenses can be determined. There is a risk that the accuracy may deteriorate. According to the above configuration, assembly can be easily performed with sufficient positioning accuracy.

  Also in the combination lens according to the present invention, for example, the first curved surface is a mortar-shaped conical surface with the optical axis as the center, and the second curved surface is three or more having a curved surface in point contact with the conical surface. A protruding portion may be provided. In other words, the combination lens according to the present invention is a combination lens including at least a first lens and a second lens, and the first lens is a mortar centered on the first contact region and the optical axis. The second lens has a second contact region that contacts the first contact region, and three or more projecting portions having a curved surface that makes point contact with the conical surface. May be.

  In the combination lens according to the present invention, for example, the second curved surface is a convex conical surface with the optical axis as the center, and the first curved surface has three or more protrusions having a curved surface in point contact with the conical surface. A site may be provided. In other words, the combination lens according to the present invention is a combination lens including at least a first lens and a second lens, and the second lens is convex with the second contact region and the optical axis as the center. The first lens may include a first contact region that contacts the second contact region, and three or more projecting portions having a curved surface that makes point contact with the conical surface. Good.

  According to said structure, the distance of the optical axis direction between both lenses is prescribed | regulated by the 1st curved surface with which a 1st lens is provided, and the 2nd curved surface with which a 2nd lens is provided. Then, when the first contact region provided in the first lens and the second contact region provided in the second lens are in contact with each other, the inclination between the two lenses is defined, and the optical axes of both lenses can be aligned. . As described above, the combination lens according to the present invention can adjust the relative position between the lenses without the need for another adjustment mechanism by contacting the lenses.

  At this time, the contact between the first curved surface and the second curved surface is a point contact between the conical surface and three or more projecting portions having curved surfaces in point contact with the conical surface. Therefore, the tilt between the two lenses is not completely defined by the contact. As a result, when the first lens and the second lens are fitted, the first contact area and the second contact area can be obtained even when the first lens and the second lens are combined in a slightly tilted state. The tilt is canceled by bringing the lens into contact with each other. Therefore, the first lens and the second lens can be easily fitted with high accuracy without a highly accurate assembly device.

  Furthermore, since the contact is a point contact, unlike the case of surface contact, it is not over-constrained and the lenses can be fitted with high accuracy.

  As described above, the combination lens according to the present invention has an effect that the relative position between the lenses can be adjusted with high accuracy and easily by the contact of the lenses.

  In the combination lens, it is preferable that the intersection of the normals of the curved surfaces at the contact point with the conical surface is on the optical axis. Furthermore, in the combination lens, it is more preferable that the distances between the contact points and the intersections are equal to each other.

  According to the above configuration, even if the second lens is tilted with respect to the first lens, it is tilted around the intersection point on the optical axis, and the tilt correction is a simple rotational motion. The tilt can be easily corrected. In particular, when the distances between the contact points and the intersections are equal to each other, the rotational motion is a circular motion, and the tilt can be corrected more easily.

  In the combination lens, it is preferable that the curved surface is a spherical surface, and a radius of the spherical surface is equal to or less than a distance between the contact points and the intersection.

  According to said structure, the said curved surface turns into a spherical surface whose radius is below the distance between each said contact and the said intersection. Thereby, since the rotational motion centering on the intersection is not hindered by the contact between the curved surface and the conical surface at each contact point, the inclination can be easily corrected.

  In the combination lens, it is preferable that a plane including the contact points of the curved surfaces and the conical surface is orthogonal to the optical axis.

  According to the configuration described above, it is possible to perform a reasonable correction by applying a force in a direction along the optical axis when correcting the tilt.

  In the combination lens, it is preferable that the first contact area and the second contact area are in contact with each other on a plane perpendicular to the optical axis.

  According to the above configuration, the contact between the first contact region and the second contact region does not define the relative position between the first lens and the second lens in a plane perpendicular to the optical axis. Therefore, it is not over-constrained and the lenses can be fitted with high accuracy.

  In the combination lens, one of the first contact region and the second contact region may be a flat surface, and the other may be a plurality of protrusions.

  According to said structure, since a 1st contact area | region and a 2nd contact area | region are in point contact, it can be made to contact with higher precision.

  In the combination lens, the first contact area and the second contact area may be formed of planes parallel to each other.

  According to said structure, since a 1st contact area | region and a 2nd contact | abutting area | region make surface contact between planes, it can contact more stably.

  In the combination lens, the first lens may include a flat portion perpendicular to the optical axis on the opposite side of the surface facing the second lens.

  According to said structure, a 1st lens can be made to contact | abut favorably to another member, for example, the lens barrel for storing the said combination lens, in the said plane part.

  In the combination lens, the second lens may include a plane portion perpendicular to the optical axis on the opposite side of the surface facing the first lens.

  According to said structure, a 2nd lens can be made to contact | abut favorably to another member, for example, the lens barrel for storing the said combination lens, in the said plane part.

  A lens unit according to the present invention is a lens unit including a lens barrel having a first opening and a second opening, and the above-described combination lens inserted in the lens barrel. The portion can be inserted with the combination lens, and the lens barrel is in contact with the flat portion of the combination lens at the peripheral edge of the second opening.

  According to said structure, the lens unit provided with the combination lens which can adjust the relative position between lenses accurately and easily can be provided. Further, since the combination lens is provided with the flat portion as described above, it can be easily combined with the lens barrel.

  An imaging apparatus according to the present invention includes the lens unit and an imaging element.

  According to said structure, the imaging device provided with the combination lens which can adjust the relative position between lenses accurately and easily can be provided.

  An optical apparatus according to the present invention includes at least one of the combination lens, the lens unit, and the imaging device.

  It is possible to provide an optical apparatus including a combination lens that can easily and accurately adjust the relative position between lenses.

  According to the combination lens according to the present invention, the contact between the first curved surface provided in the first lens and the second curved surface provided in the second lens makes it possible to correct the inclination in the optical axis direction between the two lenses. The distance is adjusted, and the inclination is adjusted by the contact between the first contact region provided in the first lens and the second contact region provided in the second lens. There is no constraint, and the relative position between the lenses can be adjusted with high accuracy and ease.

[First Embodiment]
FIG. 1 is a cross-sectional view schematically showing a combination lens 10 according to an embodiment of the present invention. As shown in FIG. 1, the combination lens 10 includes a lens (first lens) 11 and a lens (second lens) 12. The lens 11 and the lens 12 have a common optical axis 13.

  The lens 11 has an optically effective range 11c around the optical axis 13 that is a range through which light passes when the combination lens 10 is used. In addition, the lens 11 is provided with a mortar-shaped conical surface (slope) 11a centered on the optical axis 13 outside the optically effective range 11c. The “mortar-shaped conical surface” is an inner wall of the dent, and is intended to be a conical surface whose radius decreases as it becomes deeper like a mortar. Further, the lens 11 is provided with a contact region (first contact region) 11b formed of a plane perpendicular to the optical axis 13 outside the conical surface 11a.

  On the other hand, the lens 12 has an optically effective range 12c around the optical axis 13 that is a range through which light passes when the combination lens 10 is used. Further, the lens 13 is provided with a curved surface 12a constituted by a part of a spherical surface 15 having a center 14 on the optical axis 13 outside the optical effective range 13c. Further, the lens 12 is provided with a contact area (second contact area) 12b formed of a plane perpendicular to the optical axis 13 outside the curved surface 12a.

  The lens 11 and the lens 12 may be formed of glass, resin material, or the like by a well-known and commonly used molding technique or the like, as long as the optimum refractive index and curvature radius are appropriately selected according to the optical design. When the shape of the lens or the peripheral structure is complicated, a resin material that is formed by molding can be suitably used.

  In this embodiment, as shown in FIG. 1, the optical effective range of each lens is different, but these may be equal.

  The lens 11 and the lens 12 are in contact with each other so that the curved surface 12a is accommodated in the conical surface 11a, and the contact region 11b and the contact region 12b are in contact. Here, since the contact between the conical surface 11a and the curved surface 12a is a contact between the conical surface and the spherical surface, it is in a line contact or a state close to a line contact. Therefore, the contact between the conical surface 11 a and the curved surface 12 a does not define the inclination of the lens 12 with respect to the lens 11. Thus, even when the lens 12 is inserted into the lens 11 in the tilted state and the conical surface 11a and the curved surface 12a are in contact with each other, the tilt can be corrected as described later. In addition, it is preferable that the surface state of the conical surface 11a and the curved surface 11b is a surface state with good sliding. In addition, in this specification, the term “line contact” is intended to mean that a specific member and another member are in contact with each other in a line having a line width of 0.1 mm or less.

  In addition, the case where it will be in the state close | similar to the said line contact includes the case where the tangent plane of the conical surface 11a and the curved surface 12a does not correspond in the contact point of the conical surface 11a and the curved surface 12a, for example. In this case, it is considered that either one or both of the conical surface 11a and the curved surface 12a are slightly deformed to locally make a surface contact state. As a result, the frictional force increases, and the lens 12a is inserted. There is a possibility that the self-alignment effect on the tilt of time may be hindered. Therefore, it is preferable that the tangent planes coincide.

  When the tangent planes coincide with each other, the conical surface 11 a and the curved surface 12 a are in line contact with each other in a circle having a center on the optical axis 13. When the tangent planes coincide with each other, the top of the cone 16 formed by rotating a straight line passing through the point where the conical surface 11a and the curved surface 12a abut and the center 14 of the spherical surface 15 constituting the curved surface 12a around the optical axis 13 is rotated. When the angle is θ, the apex angle of the cone 17 including the conical surface 11a is 180−θ. Even if the lens 12 is inclined with respect to the lens 11, the center 14 of the inclination is fixed at one point on the optical axis 13, and the contact area 11b and the contact area 12b come into contact with each other. The tilt is corrected via.

  In the present embodiment, the curved surface 12a is a spherical surface, but other curved surfaces may be used depending on the lens shape or the space around the lens.

  For example, if it is difficult to secure a space in a certain direction, a configuration in which the short sides of an ellipse are arranged may be used. That is, an elliptical surface may be used as the curved surface 12a. Even when an elliptical surface is used as the curved surface 12a, the contact between the conical surface and the ellipsoidal surface is a line contact or a state close to a line contact. Therefore, as in the present embodiment, the conical surface 11a and the curved surface 12a The contact does not define the tilt of the lens 12 with respect to the lens 11, and the tilt is corrected even when the lens 12 is inserted in the tilted state and the conical surface 11a and the curved surface 12a are in contact with each other. be able to.

  Also, other curved surfaces may be used as long as the contact between the conical surface 11a and the curved surface 12a is a line contact as a result of combining the lens 11 and the lens 12. If the contact is a line contact, the same effect as the present embodiment is obtained.

  However, when a spherical surface is used, as described above, the center of inclination 14 is fixed at one point on the optical axis 13, and the inclination is corrected via a simple rotational motion, which is more preferable.

  FIG. 2 is a schematic diagram for explaining the function of the combination lens 10 according to the present embodiment. As shown in FIG. 2, when the curved surface 12a of the lens 12 comes into contact with the conical surface 11a of the lens 11, the center 14 of the spherical surface 15 constituting the curved surface 12a is on the central axis (that is, the optical axis 13) of the cone 16. Is positioned. Therefore, if the lens 12 is combined with the lens 11 tilted, the optical axis 18 of the lens 12 is tilted around the center 14 of the spherical surface 15 with respect to the optical axis 13 of the lens 11. It becomes. Then, the abutment region 11b, which is a plane perpendicular to the optical axis 13 of the lens 11, and the abutment region 12b, which is a plane perpendicular to the optical axis 18 of the lens 12, are in contact with each other, thereby suppressing or correcting the inclination. Can do. Even if the lens 12 is stored in the lens 11, even if it is inserted in an inclined state, the contact between the conical surface 11a and the curved surface 12a, and the contact between the contact region 11b and the contact region 12b, The positions and inclinations of the optical axes 13 and 18 can be positioned simultaneously. Therefore, the first lens and the second lens can be easily fitted with high accuracy without a highly accurate assembly device.

  Further, since the contact between the conical surface 11a and the curved surface 12a is substantially a line contact, unlike the case where the contact is entirely a surface contact, it is not over-constrained and the lenses are fitted with high accuracy. be able to.

  In the present embodiment, the contact area 11b and the contact area 12b are in contact with each other on a plane perpendicular to the optical axis 13, but the present invention is not limited to this. That is, in addition to the contact between the conical surface 11a and the curved surface 12a, it is important that the contact region 11b and the contact region 12b are in contact with each other, thereby correcting the inclination between the two lenses. Can do. However, when the contact area 11b and the contact area 12b are in contact with each other in a plane perpendicular to the optical axis 13, the contact is relative to the first lens and the second lens in the plane perpendicular to the optical axis. The position is not specified. Therefore, it is preferable that the contact region 11b and the contact region 12b are in contact with each other in a plane perpendicular to the optical axis 13, since the lenses can be fitted with high accuracy without being over-constrained.

  In the present embodiment, the contact areas 11b and 12b are flat, but the present invention is not limited thereto. That is, it is only necessary to be able to define the inclination between the two lenses by the contact between the contact region 11b and the contact region 12b, and the contact may be a surface contact or a line contact. It may be a contact. For example, a flat surface may be used as one of the contact regions 11b and 12b, and a plurality of dot-like projections or annular projections may be provided so that the contact portion is on a plane perpendicular to the optical axis 13. . In particular, by providing the point-like projections at three positions with good balance, the plane formed by the projections and the other plane can be brought into contact with each other with high accuracy. On the other hand, when the contact areas 11b and 12b are flat, they can be stably contacted.

  Furthermore, in the combination lens 10 according to the present embodiment, as the angle θ is larger, the inclination is more easily corrected, and the accuracy of the jig or the assembly device at the time of assembly is not required. There is a possibility that the positioning accuracy of the relative position is deteriorated. On the other hand, when the angle θ is smaller than 60 degrees, the free movement (tilt) of the spherical surface within the cone is hindered, and the tilt (tilt) cannot be determined by the contact of the contact regions 11b and 12b. There is. Therefore, the angle θ is preferably in the range of 60 degrees to 120 degrees. Further, for example, when there is a margin in the lens outer peripheral portion, the angle θ is set to be small. Conversely, when there is no margin in the lens outer peripheral portion, the angle θ is increased to make the inclination parallel to the optical axis. It is preferable to adopt a configuration.

[Second Embodiment]
Another embodiment of the present invention will be described with reference to FIG. FIG. 3 is a cross-sectional view schematically showing the combination lens 20 according to the present embodiment. As shown in FIG. 3, the configuration of the combination lens 20 is substantially the same as that of the combination lens 10 in the first embodiment. However, in the lens (first lens) 21, the conical surface 21 a has a contact region (first contact). (Contact area) 21b is closer to the optical axis 23 than the contact area) 21b. In the lens (second lens) 22, the curved surface 22a is closer to the optical axis 23 than the contact area (second contact area) 22b. Is different in that it is provided.

  Specifically, the combination lens 20 includes a lens 21 and a lens 22, and the lens 21 has a mortar-shaped conical surface (slope) centered on the optical axis 23 outside the optically effective range 21 c. 21a and a contact area 21b formed of a plane perpendicular to the optical axis 23. The lens 22 is constituted by a spherical surface 25 having a center 24 on the optical axis 23 in addition to the optical effective range 22c. A curved surface 22a, and a contact area 22b composed of a plane perpendicular to the optical axis 23.

  The contact region 21b is located at a position inside the conical surface 21a (close to the optical axis 23), and the contact region 22b is cut out from the top of the spherical surface 25 inside the curved surface 22a (close to the optical axis 23). It is provided at the position. The lens 21 and the lens 22 come into contact with the conical surface 21a so that the curved surface 22a is housed, and the contact area 21b and the contact area 22b come into contact with each other to be combined.

  The combination lens 20 according to the present embodiment includes the lens 21 and the lens even when the overall size of the combination lens 20 is reduced as compared with the combination lens 10 according to the first embodiment. 22 can be combined with high accuracy.

  That is, when reducing the outer shape of the combination lens 10 according to the first embodiment, it is necessary to reduce the angle θ and the width (dimension) L of the outer peripheral portion of the conical surface 11a. In this case, the conical surface 11a has a thin shape, and when the curved surface 12a is brought into contact with the conical surface 11a, the conical surface 11a is deformed, and the inclination of the contact region 11b may be shifted from the contact region 12b. There is.

  On the other hand, when the outer shape of the combination lens 20 according to the present embodiment is reduced, similarly, a straight line passing through the point where the conical surface 21a and the curved surface 22a abut and the center 24 of the spherical surface 25 constituting the curved surface 22a is taken as the optical axis. It is necessary to reduce the apex angle θ of the cone 26 rotated around the diameter 23 and to reduce the width (dimension) L of the outer peripheral portion of the conical surface 21a. Similarly, the conical surface 11a has a thin shape, and when the curved surface 12a is brought into contact with the conical surface 11a, the conical surface 11a may be deformed. There is no possibility that the inclination is shifted from the contact region 12b.

  In particular, when the angle L is less than 60 degrees and the length L is 0.3 mm or less, it is preferable to use the combination lens 20 according to the present embodiment. On the other hand, in other cases, even when the combination lens 10 according to the first embodiment is used, there is little possibility that the inclination of the contact area 11b is shifted from the contact area 12b. In this case, the combination lens 10 according to the first embodiment can effectively use the outer peripheral portion of the conical surface 11a.

[Third Embodiment]
Still another embodiment of the present invention will be described with reference to FIG. FIG. 4 is a cross-sectional view schematically showing the lens unit 30 according to the present embodiment. As shown in FIG. 4, the lens unit 30 includes a lens (first lens) 31, a lens (second lens) 32, and a lens barrel 38. In addition to the optically effective range 31 c, the lens 31 includes a mortar-shaped conical surface 31 a centered on the optical axis 33, and a contact area (first contact area) 31 b formed of a plane perpendicular to the optical axis 33. It has. In addition to the optical effective range 32 c, the lens 32 includes a curved surface 32 a configured by a spherical surface 35 having a center 34 on the optical axis 33 and a contact region (second contact region) formed by a plane perpendicular to the optical axis 33. ) 32b.

  The lens barrel 38 includes a first opening (upper part in the figure) and a second opening (lower part in the figure). The diameter of the first opening is smaller than the diameters of the lens 31 and the lens 32, and the second The diameter of the opening is equal to or larger than the diameter of the lens 31 and the lens 32. Therefore, the lens 31 and the lens 32 can be inserted into the lens barrel 38 from the second opening, and the lens can be held by bringing the lens 31 or the lens 32 into contact with the peripheral edge of the first opening. .

  The method for inserting the lens 31 and the lens 32 into the lens barrel 38 is not particularly limited. For example, the lens 32 may be combined with the lens 31 after the lens 31 is inserted into the lens barrel 38. In this case, the apex angle θ of the cone 36 formed by rotating a straight line passing through the point where the conical surface 31a and the curved surface 32a abut and the center 34 of the spherical surface 35 constituting the curved surface 32a around the optical axis 33 is small, Even when the width (dimension) L of the outer peripheral portion of the conical surface 31a is small, the lens barrel 38 holds the lens 31, so that deformation of the conical surface 31a is suppressed. Therefore, even if the contact area 31b is provided on the outer periphery of the conical surface 31a, there is no possibility that the inclination between the contact areas is shifted as described above. When the contact region 31b is provided on the outer periphery of the conical surface 31a, it is not necessary to provide a new contact region inside the conical surface 31a, so that the lens 31 can be reduced in size.

  It is also possible to first fit the lenses and then insert them into the lens barrel 38. This method is particularly suitable when the length L is large and the deformation of the shape is considered to be small as in the first embodiment.

  Of the lens 31 and the lens 32, the lens that contacts the peripheral edge of the first opening of the lens barrel 38 is provided with a flat surface portion 31d or 32d formed of a plane perpendicular to the optical axis 33 at the corresponding contact portion. Preferably it is. The lenses 31 and 32 are preferably attached to the lens barrel 38 by bringing the flat surface portion 31d or 32d into contact with the peripheral edge portion of the first opening of the lens barrel 38 provided so as to be perpendicular to the side surface of the lens barrel 38. Can be retained.

  At this time, as shown in FIG. 4, the flat surface portion 31 d of the lens 31 may abut on a surface perpendicular to the side surface of the lens barrel 38, or conversely, the flat surface portion 32 d of the lens 32 is in contact with the side surface of the lens barrel 38. You may contact | abut to a perpendicular | vertical surface.

  For example, as shown in FIG. 4, when the optical effective range 31 c of the lens 31 is narrower than the optical effective range 32 c of the lens 32, the planar portion 31 d of the lens 31 is connected to the periphery of the first opening of the lens barrel 38. It is preferable to use the peripheral portion as a diaphragm, because it is not necessary to newly provide a diaphragm.

  Further, when the flat surface portion 32d of the lens 32 is brought into contact with the peripheral edge portion of the first opening of the lens barrel 38, light rays that do not pass through the optically effective range of the lens 31 and the lens 32, that is, stray light can be blocked. it can.

[Fourth Embodiment]
FIG. 6 is a cross-sectional view schematically showing the combination lens 40 according to an embodiment of the present invention. As shown in FIG. 6, the combination lens 40 includes a lens (first lens) 41 and a lens (second lens) 42. The lens 41 and the lens 42 have a common optical axis 43.

  The lens 41 has an optically effective range 41c around the optical axis 43, which is a range through which light passes when the combination lens 40 is used. In addition, the lens 41 is provided with a mortar-shaped conical surface (slope) 41a centered on the optical axis 43 outside the optically effective range 41c. The “mortar-shaped conical surface” is an inner wall of the dent, and is intended to be a conical surface whose radius decreases as it becomes deeper like a mortar. Further, the lens 41 is provided with a contact area (first contact area) 41b made of a plane perpendicular to the optical axis 43 outside the conical surface 41a.

  On the other hand, the lens 42 has an optically effective range 42 c around the optical axis 43, which is a range through which light passes when the combination lens 40 is used. Further, the lens 42 is provided with a projecting portion having a curved surface 42a constituted by a part of the spherical surface 45 outside the optically effective range 42c. FIG. 7 shows a front view from the concave surface of the lens 42. Thus, the projecting portions having the curved surface 42a are partially provided at three equal intervals of about 120 ° around the optical axis. Further, FIG. 8 shows a perspective view seen from the lower side of the sheet of FIG. As shown in FIG. 8, the extended line of the normal line 46 of the curved surface 42 a provided at this protruding portion has an intersection 44 on the optical axis 43. Further, the lens 42 is provided with a contact area (second contact area) 42b formed of a plane perpendicular to the optical axis 43 outside the curved surface 42a.

  The lens 41 and the lens 42 may be formed of glass, resin material, or the like by a well-known and commonly used molding technique or the like, as long as the optimum refractive index and curvature radius are appropriately selected according to the optical design. When the shape of the lens or the peripheral structure is complicated, a resin material that is formed by molding can be suitably used.

  In this embodiment, as shown in FIG. 6, the optical effective range of each lens is different, but these may be equal.

  In the lens 41 and the lens 42, a projection portion having a curved surface 42a is housed in a conical surface 41a, and the conical surface 41a and the curved surface 42a are in contact with each other, and the contact region 41b and the contact region 42b are in contact with each other. ing. Here, the contact between the conical surface 41a and the curved surface 42a is a contact between the conical surface and the curved surface, and is in a substantially point contact state. Since the contact points are within one plane, the contact between the conical surface 41 a and the curved surface 42 a does not define the inclination of the lens 42 with respect to the lens 41. Thus, the tilt can be corrected even when the lens 42 is inserted into the lens 41 in a tilted state and the conical surface 41a and the curved surface 42a are in contact with each other. In addition, it is preferable that the surface state of the conical surface 41a and the curved surface 41b is a surface state with good slip. In this specification, the term “point contact” is intended to mean that a specific member and another member are in contact with each other in a circle having a diameter of 0.1 mm or less.

  In addition, since the contact area becomes smaller by the point contact than in the case of surface contact, the frictional force can be reduced. For this reason, it is possible to sufficiently exhibit the effect of the self-alignment effect on the inclination when the lens 42a is inserted.

  When the conical surface 41a comes into contact with the three points of the curved surface 42a of the projection portion of the lens 42, the distance from the contact point between the conical surface 41a and the curved surface 42a to the intersection point on the extension line of the normal line of the curved surface 42b at the contact point is It is preferable that they are located equidistant from each other. The plane including these three contact points is preferably perpendicular to the optical axis. As a result, when the lens 42 is tilted with respect to the lens 41, contact is made at three points or less, and since the lens 42 is in an unstable state, the tilt is corrected through a simple rotational movement so that the three points come into contact. The In particular, even when the radius of the curved surface 42a of the projection portion is equal to the length of the intersection of the conical surface and the curved surface contact point between the normal line of the contact point and the optical axis, the lens 42 may be inclined with respect to the lens 41. The center of inclination 44 is fixed at one point on the optical axis 43, and the contact area 41b and the contact area 42b come into contact with each other, so that the inclination is corrected through a simple rotational movement, which is more preferable. . In addition, when the plane including these three contact points is perpendicular to the optical axis, it is possible to make a reasonable correction by applying a force in a direction along the optical axis when correcting the tilt.

  In the present embodiment, the curved surface 42a is a spherical surface, but other curved surfaces may be used depending on the lens shape or the space around the lens.

  For example, if it is difficult to secure a space in a certain direction, a configuration in which the short sides of an ellipse are arranged may be used. That is, an elliptical surface may be used as the curved surface 42a. Even when an elliptical surface is used as the curved surface 42a, the contact between the conical surface and the elliptical surface of the projecting portion is in a substantially point contact state, so that the conical surface 41a and the curved surface 42a The contact does not define the tilt of the lens 42 with respect to the lens 41, and the tilt is corrected even when the lens 42 is inserted into the lens 41 in the tilted state and the conical surface 41a and the curved surface 42a are in contact with each other. be able to.

  Also, other curved surfaces may be used as long as the contact between the conical surface 41a and the curved surface 42a becomes a substantially point contact as a result of combining the lens 41 and the lens 42. If the contact is substantially a point contact, the same effects as in the present embodiment are obtained.

  Next, with reference to FIG. 8, the protrusion part which has the curved surface provided in the lens 42 is demonstrated. As described above, the lens 42 has the curved surface 42a forming a part of the spherical surface 45 as a projecting portion, and this 42a has a point 42a 'which is in contact with the conical surface 41a of the corresponding lens 41. In FIG. 8, the normal lines of the contact points 42 a ′ intersect the intersection points on the optical axis 43 at three points of the projecting portion.

  The smaller the radius of the spherical surface 45, the smaller the contact area and the smooth contact with the desired position. However, when the radius is too small, the deformation and the effect are not exerted in the first place. On the other hand, when the radius becomes large, there is a possibility that contact at an unintended point occurs. However, when the radius is a spherical surface equal to the length from the contact point between the curved surface of the projection and the conical surface to the intersection of the normals, that is, when the radius is the normal 46 shown in FIG. Is fixed at one point on the optical axis 43, the inclination is corrected through a simple rotational motion.

  In the present invention, since the contact between the conical surface 41a and the curved surface 42a of the projecting portion is reliably point contact, surface contact and line contact are prevented, and the lens is not over-constrained, and the lens The fitting between each other can be performed with high accuracy.

  In the present embodiment, the contact area 41b and the contact area 42b are in contact with each other on a plane perpendicular to the optical axis 43, but the present invention is not limited to this. That is, in addition to the contact between the conical surface 41a and the curved surface 42a, it is important that the contact region 41b and the contact region 42b are in contact with each other, thereby correcting the inclination between the two lenses. Can do. However, when the contact area 41b and the contact area 42b are in contact with each other in a plane perpendicular to the optical axis 43, the contact is relative to the first lens and the second lens in the plane perpendicular to the optical axis. The position is not specified. Therefore, it is preferable that the contact area 41b and the contact area 12b are in contact with each other in a plane perpendicular to the optical axis 13 because the lenses can be fitted with high accuracy without being over-constrained.

  In the present embodiment, the contact areas 41b and 42b are flat surfaces, but the present invention is not limited to these. That is, it is only necessary to be able to define the inclination between the two lenses by contacting the contact area 41b and the contact area 42b. The contact may be a surface contact or a line contact. It may be a contact. For example, a flat surface may be used as one of the contact regions 41b and 42b, and a plurality of dot-like projections or annular projections may be provided so that the contact portion is on a plane perpendicular to the optical axis 43 as the other. . In particular, by providing the point-like projections at three positions with good balance, the plane formed by the projections and the other plane can be brought into contact with each other with high accuracy. On the other hand, when the contact areas 41b and 42b are flat, they can be stably contacted.

  Furthermore, in the combination lens 40 according to the present embodiment, it is preferable that the curved surface of the projecting portion is a spherical surface, and a smaller radius is preferable because the contact area becomes smaller when the lens 41 and the lens 42 are combined, but the smaller the radius. If it is too much, sufficient effects will not be exhibited due to deformation. On the other hand, when the radius is large, the contact area becomes large, and there is a possibility of contact at an unintended point. The radius is preferably from 0.05 mm, which is defined as point contact in the present invention, to the length from the point of intersection of the point where the conical surface and curved surface abut on the lens optical axis.

[Fifth Embodiment]
Another embodiment of the present invention will be described with reference to FIG. FIG. 9 is a cross-sectional view schematically showing the combination lens 50 according to the present embodiment. As shown in FIG. 9, the configuration of the combination lens 50 is substantially the same as that of the combination lens 40 in the fourth embodiment. However, the lens (first lens) 51 is provided with a protruding portion having a curved surface 51a. In the lens (second lens) 52, the point provided with the convex conical surface 52a and the curved surface (the curved surface 51a and the conical surface 52a) are more than the contact regions (the contact region 51b and the contact region 52b). The difference is that it is provided at a position far from the optical axis 53. The “convex conical surface” is intended to be a curved surface that is a convex and conical surface, in other words, a curved surface that is the outer surface of a cone.

  Specifically, the combination lens 50 includes a lens 51 and a lens 52, and the lens 51 is configured by a spherical surface 55 having a normal line intersection 54 on the optical axis 53 outside the optically effective range 51c. The projection 52 having a curved surface 51a and a contact area 51b composed of a plane perpendicular to the optical axis 53 are included. The lens 52 is centered on the optical axis 53 outside the optically effective range 52c. And a convex conical surface 52 a and a contact area 52 b formed of a plane perpendicular to the optical axis 53.

  The contact region 51b is located at a position inside the projection part having the curved surface 51a (close to the optical axis 53), and the contact region 52b is provided at a position inside the cone surface 52a (close to the optical axis 53). It has been. The lens 51 and the lens 52 are accommodated in such a manner that a protruding portion having a curved surface 52a comes into contact with the conical surface 52a, and the contact area 51b and the contact area 52b come into contact with each other.

  As described above, even when the lens 51 is provided with the protruding portion, the same effect as that of the fourth embodiment is obtained. Further, even when the curved surface is at a position farther from the optical axis 53 than the contact area, the same effect as in the fourth embodiment is obtained, and the size of the combined lens 50 as a whole is larger than that in the fourth embodiment. Even when the size is reduced, the lens 51 and the lens 52 can be combined with high accuracy.

  That is, when reducing the outer shape of the combination lens 40 according to the fourth embodiment, it is necessary to reduce the width (dimension) L of the outer peripheral portion of the conical surface 41a. In that case, the conical surface 41a has a thin shape, and when the curved surface 42a of the protruding portion is brought into contact with the conical surface 41a, the conical surface 41a is deformed, and the inclination of the contact region 41a is shifted from the contact region 42b. There is a risk that.

  On the other hand, when the outer shape of the combination lens 50 according to the present embodiment is reduced, similarly, a straight line passing through the point where the conical surface 52a and the curved surface 51a abut and the center 54 of the spherical surface 55 constituting the curved surface 51a is taken as the optical axis. It is necessary to reduce the apex angle θ of the cone 56 rotated around 53 and to reduce the width (dimension) L of the outer peripheral portion of the conical surface 51a. Similarly, the conical surface 51a has a thin shape, and when the curved surface 52a is brought into contact with the conical surface 51a, the conical surface 51a may be deformed. There is no possibility that the inclination will deviate from the contact area 52b.

  As described in the fourth embodiment, it is preferable that the radius of the curved surface of the projection is small. However, if the radius is too small, the effect is not exhibited. When the radius is large, there is a possibility of contact at an unintended point. The radius is preferably from 0.05 mm, which is defined as point contact in the present invention, to the length from the point of intersection of the point where the conical surface and curved surface abut on the lens optical axis.

[Other Embodiments]
Although the case where the combination lens according to the present invention is configured by two lenses has been described above, the combination lens according to the present invention may be configured by three or more lenses. In this case, the contact between all the lenses may be performed in the same manner as the contact between the two lenses described above, or the contact between the two lenses described above with respect to the contact between some lenses. You may carry out similarly. That is, in the combination lens according to the present invention, a part or all of the lenses have a conical surface in the shape of a mortar centered on the optical axis and a plane perpendicular to the optical axis in a fitting portion between the lenses. And a configuration in which the other lens has a curved surface such as a spherical surface centered on the optical axis, and a contact region such as a plane perpendicular to the optical axis. Accordingly, the position and inclination of the optical axis can be easily positioned by the contact between the conical surface and the curved surface as described in the above embodiment and the contact between the contact regions.

  Further, the relationship between the lens barrel and the lens contact described in the third embodiment is also related to the assembly accuracy of the optical system composed of a plurality of lenses and the lens barrel.

  For example, in an optical system optimized by optical design, there is a lens that is sensitive to decentering or tilting of the lens. It is important that such a lens is used as a reference for assembling an optical system, and that another lens is assembled with the lens so as to be assembled with as high accuracy as possible. Note that a lens sensitive to decentering or tilting of the lens can be arbitrarily set depending on the optical design, and may be set according to the situation in which the optical system is used.

  In the above embodiment, the conical surface, the curved surface, and the contact area are provided outside the optical effective range of the lens. However, if there is no problem with the optical characteristics of the lens, the optical effective range is not exceeded. May be provided.

  The combination lens in the present invention can also be an optical system that forms an image on an image pickup device by optical design, for example, and can be an image pickup device by being integrated with the image pickup device. Can also be applied.

  Examples of the imaging device include a camera module mounted on an imaging device such as a digital still camera or a mobile phone. In such a camera module, there is a demand for downsizing, thinning, etc. of an imaging device, drop impact resistance due to being carried, or high pixels. Therefore, a configuration that allows easy fitting of a highly accurate lens like the combination lens in the present invention is becoming more and more important.

  Examples of the optical device include devices such as the above-described imaging devices such as the digital still camera and the mobile phone, information reading device game machines equipped with combination lenses, personal computers, and portable information terminals. In the combination lens of the present invention, it is possible to provide a highly accurate combination lens with a simple fitting structure for all devices that require the lens.

  The present invention can also be expressed as follows.

(First configuration)
Consisting of at least two lenses,
Peripheral portions other than the optical effective range of the adjacent first lens and second lens are
The first lens comprises a slope centered on the optical axis and a first region perpendicular to the optical axis,
The second lens consists of a curved surface and a second region perpendicular to the optical axis,
The slope and the curved surface are opposed to each other, and
A combination lens, wherein the first region and the second region are opposed to each other.

(Second configuration)
The combination lens according to the first configuration, wherein the first region and the second region are in contact with each other at an outermost peripheral portion of the peripheral portion.

(Third configuration)
The combination lens according to the first configuration, wherein the first region and the second region are in contact with each other at the innermost peripheral portion of the peripheral portion.

(Fourth configuration)
The combination lens according to any one of the first to third configurations, wherein the curved surface has the inclined surface as a contact surface.

(Fifth configuration)
The combination lens according to any one of the first to fourth configurations, wherein the curved surface is a spherical surface having the inclined surface as a contact surface and having a center on the optical axis.

(Sixth configuration)
A vertex angle of a cone formed by rotating a line passing through the point where the inclined surface and the spherical surface abut and passing through the center of the spherical surface around the optical axis is between 60 degrees and 120 degrees. The combination lens described in the structure.

(Seventh configuration)
A combination lens comprising at least a first lens and a second lens,
The first lens includes a first contact region and a mortar-shaped conical surface centered on the optical axis.
The second lens includes at least three or more projecting portions having a second contact region that contacts the first contact region and a curved surface that makes point contact with the conical surface.

(Eighth configuration)
A combination lens comprising at least a first lens and a second lens,
The first lens includes a first contact region and at least three or more projecting portions having a curved surface,
The second lens includes a second contact region that contacts the first contact region, and a conical surface that makes point contact with the curved surface of the protruding portion.

(Ninth configuration)
The combination lens according to the eighth configuration or the ninth configuration, wherein the curved surfaces of the plurality of protrusions have an intersection point on an extension line of a normal line to a tangent to the conical surface on the optical axis of the lens. .

(Tenth configuration)
From the seventh configuration, the curved surfaces of the plurality of protrusions of the normal line are provided so that the distances of the intersection points on the optical axis of the normal line from the contact point with the conical surface are equal. The combination lens according to any one of the ninth configurations.

(Eleventh configuration)
The combined lens according to any one of the seventh to tenth configurations, wherein a plane including a point where the curved surface of the projection and the conical surface abut is perpendicular to the optical axis.

(Twelfth configuration)
The curved surface of the projection is a spherical surface, and the radius of the spherical surface is equal to or less than a distance formed between the contact point with the conical surface and an intersection point on the optical axis. A combination lens according to any one of the above.

(13th configuration)
Either one of the first region and the second region is a plane,
The other region includes at least three protrusions having a uniform height or a linear protrusion having a uniform height, and any one of the first to twelfth structures is characterized. Combination lens.

(14th configuration)
The combination lens according to any one of the first to twelfth configurations, wherein the first region and the second region are both planar.

(15th configuration)
The combination lens according to any one of the first to fourteenth configurations, wherein a planar portion that is opposed to the inclined surface provided on the first lens and is perpendicular to the optical axis is provided.

(Sixteenth configuration)
The combination lens according to any one of the first to fourteenth configurations, wherein a planar portion that is opposed to the curved surface provided on the second lens and is perpendicular to the optical axis is provided.

(17th configuration)
A combination lens according to the fifteenth configuration or the sixteenth configuration;
A lens barrel that has one opening made small and a combination lens can be inserted from the other opening,
The combination lens is inserted into the barrel;
A lens unit, wherein a planar portion provided in the combination lens is in contact with a part of a small opening of the lens barrel.

(18th configuration)
An imaging apparatus in which the lens unit according to the seventeenth configuration and an imaging element are integrated.

(19th configuration)
An optical apparatus including any one of the combination lens, the lens unit, and the imaging device described in any one of the first configuration to the eighteenth configuration.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  Moreover, all the academic literatures and patent literatures described in this specification are incorporated herein by reference.

  The present invention can be suitably applied to general optical equipment using a plurality of lenses, such as a camera module mounted on a digital camera, a mobile phone, or the like.

It is sectional drawing which shows the outline of the combination lens which concerns on one Embodiment (1st Embodiment) of this invention. It is a schematic diagram for demonstrating the function of the combination lens which concerns on one Embodiment (1st Embodiment) of this invention. It is sectional drawing which shows the outline of the combination lens which concerns on one Embodiment (2nd Embodiment) of this invention. It is sectional drawing which shows the outline of the lens unit which concerns on one Embodiment (3rd Embodiment) of this invention. It is sectional drawing which shows the outline of the combination lens which concerns on a prior art. It is sectional drawing which shows the schematic of the combination lens which concerns on one Embodiment (4th Embodiment) of this invention. It is sectional drawing which shows the front view of the 2nd lens which concerns on one Embodiment (4th Embodiment) of this invention. It is sectional drawing which shows the perspective view explaining the combination lens which concerns on one Embodiment (4th Embodiment) of this invention. It is sectional drawing which shows the schematic of the combination lens which concerns on one Embodiment (5th Embodiment) of this invention.

Explanation of symbols

10, 20, 40, 50, 100 Combination lens 11, 21, 31, 41, 51, 101 Lens (first lens)
12, 22, 32, 42, 52, 102 Lens (second lens)
11a, 21a, 31a, 41a, 51a, 101a,
102a Conical surface 12a, 22a, 32a, 42a, 52a Curved surface 11b, 21b, 31b, 41b, 51b Contact region (first contact region)
12b, 23b, 32b, 42b, 52b Contact area (second contact area)
11c, 21c, 31c, 12c, 22c, 32c,
41c, 51c Optical effective range 13, 18, 23, 33, 43, 53, 103, 104 Optical axis 14, 24, 34, 44, 54 Center 15, 25, 35, 45, 55 Spherical surface 16, 17, 26, 27, 36, 37, 46, 56 Cone 30 Lens unit 31d, 32d Plane

Claims (23)

A combination lens comprising at least a first lens and a second lens,
The first lens includes a first contact area and a first curved surface,
The second lens includes a second contact area that contacts the first contact area and a second curved surface,
A combination lens, wherein the first curved surface and the second curved surface are in contact with each other in a specific plane. A combination lens comprising at least a first lens and a second lens,
The first lens includes a first contact region and a mortar-shaped conical surface centered on the optical axis.
The second lens includes a second contact region that contacts the first contact region, and a curved surface that is a spherical surface or an elliptical surface that contacts the conical surface. A combination lens comprising at least a first lens and a second lens,
The first lens includes a first contact region and a mortar-shaped conical surface centered on the optical axis.
The second lens includes a second contact region that contacts the first contact region, and a curved surface that makes line contact with the conical surface. The first contact region and the conical surface are both provided outside the optical effective range of the first lens;
4. The combination lens according to claim 2, wherein the second contact region and the curved surface are both provided outside the optically effective range of the second lens. In the first lens, the conical surface is provided at a position closer to the optical axis than the first contact region,
5. The combination lens according to claim 2, wherein the curved surface is provided at a position closer to the optical axis than the second contact region. In the first lens, the first contact region is provided at a position closer to the optical axis than the conical surface,
5. The combination lens according to claim 2, wherein in the second lens, the second contact region is provided at a position closer to the optical axis than the curved surface.   The combination lens according to any one of claims 2 to 6, wherein a tangent plane of the curved surface and the conical surface coincides with each other at a point where the curved surface and the conical surface abut.   The combination lens according to claim 2, wherein the curved surface is a spherical surface centered on a point on the optical axis.   The apex angle of a cone formed by rotating a straight line passing through the point where the conical surface and the curved surface come into contact with the center of the spherical surface around the optical axis is within a range of 60 degrees to 120 degrees. The combination lens according to claim 8, characterized in that: A combination lens comprising at least a first lens and a second lens,
The first lens includes a first contact region and a mortar-shaped conical surface centered on the optical axis.
The second lens includes a second contact region that contacts the first contact region, and three or more projecting portions having a curved surface that makes point contact with the conical surface. A combination lens comprising at least a first lens and a second lens,
The second lens includes a second contact region and a convex conical surface centered on the optical axis.
The first lens includes a first contact region that contacts the second contact region, and three or more projecting portions having a curved surface that makes point contact with the conical surface.   The combination lens according to claim 10 or 11, wherein an intersection of each normal line of each curved surface at a contact point with the conical surface is on the optical axis.   The combination lens according to claim 12, wherein the distance between each of the contact points and each of the intersections is equal to each other. The curved surface is a spherical surface,
The combination lens according to claim 12 or 13, wherein a radius of the spherical surface is equal to or less than a distance between each of the contact points and the intersection.   The combination lens according to any one of claims 10 to 14, wherein a plane including each contact point of each curved surface and the conical surface is orthogonal to the optical axis.   The combination lens according to any one of claims 1 to 15, wherein the first contact area and the second contact area are in contact with each other in a plane perpendicular to the optical axis.   The combination lens according to any one of claims 1 to 16, wherein one of the first contact region and the second contact region is a flat surface, and the other is a plurality of protrusions.   The combination lens according to any one of claims 1 to 17, wherein the first contact region and the second contact region are formed of planes parallel to each other.   The combination lens according to any one of claims 1 to 18, wherein the first lens includes a plane portion perpendicular to the optical axis on the opposite side of the surface facing the second lens.   The combination lens according to any one of claims 1 to 19, wherein the second lens includes a plane portion perpendicular to the optical axis on the opposite side of the surface facing the first lens. A lens unit comprising a lens barrel having a first opening and a second opening, and the combination lens according to claim 19 or 20 inserted in the lens barrel,
The first opening can be inserted with the combination lens,
The lens unit, wherein the lens barrel is in contact with the flat portion of the combination lens at a peripheral portion of the second opening.   An image pickup apparatus comprising the lens unit according to claim 21 and an image pickup device.   An optical apparatus comprising at least one of the combination lens according to any one of claims 1 to 20, the lens unit according to claim 21, or the imaging device according to claim 22.

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