阅读说明：本技术 一种畸变小高精度的工业镜头 (Industrial lens with small distortion and high precision ) 是由 文志强 于 2019-12-01 设计创作，主要内容包括：本发明公开了一种畸变小高精度的工业镜头,包括沿光线的入射方向依次设置的前组镜片组件、后组镜片组件,所述前组镜片组件包括沿光线的入射方向依次放置的A1正弯月形透镜、A2正弯月形透镜、A3负弯月形透镜；所述后组镜片组件包括沿光线的入射方向依次放置的B1双凹透镜、B2双凸透镜、B3双凸透镜、B4双凸透镜、B5双凹透镜。本发明针对不同物距的使用情况,可调节前后透镜组间的中心距离,或调节后透镜组到像面的距离,获得最清晰的成像,且该镜头像素高于500万,畸变小于0.1％；用于检测设备上,光圈可调,最大可达F1.8,所用透镜均为球面镜,易于加工。(The invention discloses an industrial lens with small distortion and high precision, which comprises a front lens component and a rear lens component which are sequentially arranged along the incident direction of light rays, wherein the front lens component comprises an A1 positive meniscus lens, an A2 positive meniscus lens and an A3 negative meniscus lens which are sequentially arranged along the incident direction of the light rays; the rear group lens assembly comprises a B1 biconcave lens, a B2 biconvex lens, a B3 biconvex lens, a B4 biconvex lens and a B5 biconcave lens which are sequentially arranged along the incident direction of light rays. Aiming at the use conditions of different object distances, the central distance between the front lens group and the rear lens group or the distance between the rear lens group and the image plane can be adjusted to obtain the clearest image, the number of the pixels of the lens is more than 500 ten thousand, and the distortion is less than 0.1%; when the diaphragm is used for detection equipment, the diaphragm can be adjusted, the maximum diaphragm can reach F1.8, and all the lenses are spherical mirrors and are easy to process.)

1. The utility model provides a little high accuracy industrial lens of distortion which characterized in that: the front group of lens components comprise an A1 positive meniscus lens (1), an A2 positive meniscus lens (2) and an A3 negative meniscus lens (3) which are sequentially arranged along the incident direction of light; the rear group lens assembly comprises a B1 double concave lens (4), a B2 double convex lens (5), a B3 double convex lens (6), a B4 double convex lens (7) and a B5 double concave lens (8) which are sequentially arranged along the incident direction of light rays; the A2 positive meniscus lens (2) and the A3 negative meniscus lens (3) are cemented into a first cemented lens; the B1 biconcave lens (4) and the B2 biconvex lens (5) are cemented into a second cemented lens; and the B4 biconvex lens (7) and the B5 biconcave lens (8) are cemented into a third cemented lens.

2. The industrial lens with small distortion and high precision as claimed in claim 1, wherein: the center thickness of the A1 positive meniscus lens (1) is 2.66 +/-0.03 mm; the center thickness of the A2 positive meniscus lens (2) is 3.88 +/-0.03 mm; the center thickness of the A3 negative meniscus lens (3) is 1 +/-0.03 mm; the center thickness of the B1 biconcave lens (4) is 5.29 +/-0.03 mm; the center thickness of the B2 biconvex lens (5) is 6 +/-0.03 mm; the center thickness of the B3 biconvex lens (6) is 2.12 +/-0.03 mm; the center thickness of the B4 biconvex lens (7) is 4.26 +/-0.03 mm; the center thickness of the B5 biconcave lens (8) is 1.23 +/-0.03 mm.

3. The industrial lens with small distortion and high precision as claimed in claim 2, characterized in that: the front radius curvature and the rear radius curvature of the A1 positive meniscus lens (1) are respectively 28.77mm and 147.12 mm; the front and back radius curvatures of the A2 positive meniscus lens (2) are respectively 12.53mm and 66.77 mm; the front and rear radius curvatures of the A3 negative meniscus lens (3) are 66.77mm and 8.32mm respectively; the front and back radius curvatures of the B1 biconcave lens (4) are respectively 11.25mm and 175.85 mm; the front and back radius curvatures of the B2 biconvex lens (5) are 175.85mm and 17.55mm respectively; the front and back radius curvatures of the B3 biconvex lens (6) are respectively 95.65mm and 45.86 mm; the front and back radius curvatures of the B4 biconvex lens (7) are 21.54mm and 32.22mm respectively; the front and back radius curvatures of the B5 biconcave lens (8) are both 32.22 mm.

4. A small distortion and high precision industrial lens according to claim 3, characterized in that: the central air space between the A1 positive meniscus lens (1) and the A2 positive meniscus lens (2) is 0.27 +/-0.01 mm; the central air space between the A3 negative meniscus lens (3) and the B1 double concave lens (4) is 10.26 +/-0.01 mm; the central air space between the B2 biconvex lens (5) and the B3 biconvex lens (6) is 0.15 +/-0.01 mm; the center air space between the B3 biconvex lens (6) and the B4 biconvex lens (7) is 0.15 +/-0.01 mm.

Technical Field

The invention relates to the field of machine vision lens technology and industrial image processing, in particular to an industrial lens with small distortion and high precision.

Background

With the development of science and technology, the demands of people on industrial lenses are gradually diversified. In the field of machine vision, industrial lenses are an extremely important part. Although the pixels of the existing 25m industrial lens on the market are also high, the volume and the distortion are not small enough, so that the measurement accuracy is not high.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide the industrial lens with small distortion and high precision, which has a target surface of 2/3' CCD, has a pixel value of better than 500 ten thousand and distortion of less than 0.01 percent, and can meet the high-precision requirement of machine vision.

The invention is realized by the following modes:

the utility model provides a little high accuracy industrial lens of distortion which characterized in that: the front group of lens components comprise an A1 positive meniscus lens, an A2 positive meniscus lens and an A3 negative meniscus lens which are sequentially arranged along the incident direction of light; the rear group lens assembly comprises a B1 biconcave lens, a B2 biconvex lens, a B3 biconvex lens, a B4 biconvex lens and a B5 biconcave lens which are sequentially arranged along the incident direction of light rays; the A2 positive meniscus lens is cemented with the A3 negative meniscus lens to form a first cemented lens; the B1 biconcave lens and the B2 biconvex lens are glued to form a second cemented lens; and the B4 biconvex lens and the B5 biconcave lens are cemented into a third cemented lens.

Further, the center thickness of the A1 positive meniscus lens is 2.66 +/-0.03 mm; the center thickness of the A2 positive meniscus lens is 3.88 +/-0.03 mm; the center thickness of the A3 negative meniscus lens is 1 +/-0.03 mm; the center thickness of the B1 biconcave lens is 5.29 +/-0.03 mm; the center thickness of the B2 biconvex lens is 6 +/-0.03 mm; the center thickness of the B3 biconvex lens is 2.12 +/-0.03 mm; the center thickness of the B4 biconvex lens is 4.26 +/-0.03 mm; the center thickness of the B5 biconcave lens is 1.23 + -0.03 mm.

Further, the front and back radius curvatures of the A1 positive meniscus lens are respectively 28.77mm and 147.12 mm; the front and back radius curvatures of the A2 positive meniscus lens are respectively 12.53mm and 66.77 mm; the front and back radius curvatures of the A3 negative meniscus lens are 66.77mm and 8.32mm respectively; the front and back radius curvatures of the B1 biconcave lens are 11.25mm and 175.85mm respectively; the front and back radius curvatures of the B2 biconvex lens are 175.85mm and 17.55mm respectively; the front and back radius curvatures of the B3 biconvex lens are respectively 95.65mm and 45.86 mm; the front and back radius curvatures of the B4 biconvex lens are 21.54mm and 32.22mm respectively; the front and back radius curvatures of the B5 biconcave lens are both 32.22 mm.

Further, the central air space between the A1 positive meniscus lens and the A2 positive meniscus lens is 0.27 +/-0.01 mm; the central air space between the A3 negative meniscus lens and the B1 double concave lens is 10.26 +/-0.01 mm; the central air space between the B2 biconvex lens and the B3 biconvex lens is 0.15 +/-0.01 mm; the center air spacing between the B3 lenticular and the B4 lenticular was 0.15 ± 0.01 mm.

The invention has the beneficial effects that: aiming at the use conditions of different object distances, the central distance between the front lens group and the rear lens group or the distance between the rear lens group and the image plane can be adjusted to obtain the clearest image, the number of the lens pixels is more than 500 ten thousand, and the distortion is less than 0.1%; when the diaphragm is used for detection equipment, the diaphragm can be adjusted, the maximum diaphragm can reach F1.8, and all the lenses are spherical mirrors and are easy to process.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a graph of MTF for the present invention;

figure 3 is a graph of the distortion change of the present invention.

Detailed Description

The technical solution of the present invention is further specifically described below by way of specific examples in conjunction with the accompanying drawings. It is to be understood that the embodiments of the present invention are not limited to the following examples, and that any changes and/or modifications made thereto will fall within the scope of the present invention.