Camera module and electronic device

By using a plastic lens barrel and a specially designed anti-sloping surface and light shield in the camera module, the lens barrel structure was optimized, solving the stray light problem caused by the backlight panel of the display screen, and achieving efficient stray light elimination and improved image quality.

CN116719142BActive Publication Date: 2026-07-07LARGAN PRECISION

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
LARGAN PRECISION
Filing Date
2019-11-28
Publication Date
2026-07-07

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  • Figure CN116719142B_ABST
    Figure CN116719142B_ABST
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Abstract

A camera module and an electronic device, the camera module includes an imaging lens and an image sensor, wherein the image sensor is located on the image side of the imaging lens. The imaging lens has an optical axis and includes a plastic lens barrel and a plurality of plastic lenses, the plastic lenses are arranged in the plastic lens barrel. The plastic lens barrel includes an object end outer surface, a barrel minimum opening, an object end outer inclined surface and an inverse inclined surface. The object end outer surface is a surface of the plastic lens barrel facing the object side and closest to the object side, and is annular. The object end outer inclined surface is tapered from the object end outer surface to the barrel minimum opening. The inverse inclined surface gradually expands from the barrel minimum opening towards the image side, wherein the junction of the inverse inclined surface and the object end outer inclined surface forms the barrel minimum opening. When certain conditions are met, the structural configuration of the plastic lens barrel can maintain the manufacturing quality and eliminate stray light.
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Description

[0001] This application is a divisional application of the patent application filed on November 28, 2019, with application number 201911186799.7 and title "Camera Module and Electronic Device". Technical Field

[0002] This disclosure relates to a camera module, and more particularly to a camera module used in portable electronic devices. Background Technology

[0003] In most common camera modules, a protective glass is usually placed between the imaging lens and the subject. Since there is an air gap between the protective glass and the imaging lens, when the strong light source of the subject causes stray light, the effect of stray light can be reduced by setting a means to reduce reflection inside the imaging lens.

[0004] However, when the camera module is placed in a common electronic device with photographic function, the display screen with a light-transmitting material is placed between the imaging lens and the subject. The display screen has a backlight panel, and its light source is closer to the imaging lens than the strong light source of the subject. This not only makes it easier to affect the image quality, but also makes it impossible to eliminate the influence of stray light by setting a means to reduce reflection inside the imaging lens.

[0005] Therefore, developing a camera module that effectively eliminates stray light, has good image quality, and can be miniaturized for use in electronic devices has become an important and urgent problem for the industry. Summary of the Invention

[0006] This disclosure provides a camera module and electronic device in which manufacturing quality is maintained and stray light is eliminated through the structural configuration of the plastic lens barrel therein.

[0007] According to one embodiment of this disclosure, a camera module is provided, comprising an imaging lens and an image sensor, wherein the image sensor is located on the image side of the imaging lens. The imaging lens has an optical axis and includes a plastic lens barrel, a plurality of plastic lenses, and a light-blocking plate, wherein the plastic lenses and the light-blocking plate are disposed within the plastic lens barrel. The plastic lens barrel includes an object-end outer surface, a minimum aperture of the lens barrel, an object-end outer bevel, and a reverse bevel. The object-end outer surface is the surface of the plastic lens barrel facing the object side and closest to the object side, and is annular. The object-end outer bevel gradually tapers from the object-end outer surface towards the minimum aperture of the lens barrel. The reverse bevel gradually expands from the minimum aperture of the lens barrel towards the image side, wherein the connection between the reverse bevel and the object-end outer bevel surrounds to form the minimum aperture of the lens barrel. The number of plastic lenses is N, the distance between the minimum opening of the lens barrel and the light shield in the direction parallel to the optical axis is d, the distance between the minimum opening of the lens barrel and the outer surface of the object end in the direction parallel to the optical axis is h, the diameter of the minimum opening of the lens barrel is ψED, the opening diameter of the light shield is ψs1, and the principal ray angle between a principal imaging ray of the imaging lens corresponding to an image height of 1.0F and the image sensor is CRA1.0F, which satisfies the following conditions: 4 ≤ N ≤ 10; 1.0 < d / h < 15.0; 0.8 ≤ ψED / ψs1 ≤ 1.05; and CRA 1.0F > 25.0 degrees.

[0008] According to the camera module of the embodiment described above, the light shield is located between the smallest opening of the lens barrel and the object-side peripheral portion of the plastic lens that is closest to the object side.

[0009] According to the camera module of the embodiment described above, the anti-sloping surface includes multiple straight strip-shaped structures that extend from the minimum opening of the lens barrel toward the direction perpendicular to the optical axis.

[0010] According to the camera module of the embodiment described above, the diameter of the minimum opening of the lens barrel is ψED, and the diameter of the opening of the light shield is ψs1, which satisfies the following condition: 0.8 ≤ ψED / ψs1 ≤ 1.0.

[0011] According to the camera module of the embodiment described above, the outer inclined surface of the object end is a first conical surface, the reverse inclined surface is a second conical surface, and the angle between the first conical surface and the second conical surface through a section line of the optical axis is θ, which satisfies the following condition: 45 degrees < θ < 120 degrees.

[0012] According to another embodiment of this disclosure, an electronic device is provided, comprising a camera module as described in the preceding embodiment and a surface plate, wherein the surface plate is disposed on the object side of the camera module. The distance g between the outer surface of the object end and the surface plate in the direction parallel to the optical axis satisfies the following condition: 0.03 mm < g < 0.3 mm.

[0013] The electronic device according to the embodiments described above, wherein the surface plate is a plate with a display function module. Attached Figure Description

[0014] Figure 1A A schematic diagram of an electronic device according to a first embodiment of this disclosure is shown;

[0015] Figure 1B Drawing according to Figure 1A A schematic diagram of the surface plate in the first embodiment;

[0016] Figure 1C Drawing according to Figure 1A A schematic diagram of the surface plate and camera module in the first embodiment;

[0017] Figure 1D Drawing according to Figure 1A Another schematic diagram of the surface plate and camera module in the first embodiment;

[0018] Figure 1E Drawing according to Figure 1A A schematic diagram of the plastic lens barrel in the first embodiment;

[0019] Figure 1F Drawing according to Figure 1A A three-dimensional schematic diagram of the plastic lens barrel in the first embodiment;

[0020] Figure 1G Drawing according to Figure 1A A schematic diagram of parameters h and d in the first embodiment;

[0021] Figure 1H Drawing according to Figure 1A A schematic diagram of parameter θ in the first embodiment;

[0022] Figure 1I Drawing according to Figure 1A A schematic diagram of parameters ψD, ψED and ψs1 in the first embodiment;

[0023] Figure 2A A schematic diagram illustrating the surface plate and camera module of the electronic device according to the second embodiment of this disclosure;

[0024] Figure 2B Drawing according to Figure 2A Another schematic diagram of the surface plate and camera module in the second embodiment;

[0025] Figure 2C Drawing according to Figure 2A Another schematic diagram of the surface plate and camera module in the second embodiment;

[0026] Figure 2D Drawing according to Figure 2AA schematic diagram of parameters h and d in the second embodiment;

[0027] Figure 2E Drawing according to Figure 2A A schematic diagram of parameter θ in the second embodiment;

[0028] Figure 2F Drawing according to Figure 2A A schematic diagram of parameters ψD, ψED and ψs1 in the second embodiment;

[0029] Figure 3A A schematic diagram illustrating the surface plate and camera module of the electronic device according to the third embodiment of this disclosure;

[0030] Figure 3B Drawing according to Figure 3A A schematic diagram of parameters h and d in the third embodiment;

[0031] Figure 3C Drawing according to Figure 3A A schematic diagram of parameter θ in the third embodiment;

[0032] Figure 3D Drawing according to Figure 3A A schematic diagram of parameters ψD, ψED and ψs1 in the third embodiment;

[0033] Figure 4A A schematic diagram illustrating the surface plate and camera module of the electronic device according to the fourth embodiment of this disclosure;

[0034] Figure 4B Drawing according to Figure 4A Exploded view of the imaging lens in the fourth embodiment;

[0035] Figure 4C Drawing according to Figure 4A A three-dimensional schematic diagram of the plastic lens barrel in the fourth embodiment;

[0036] Figure 4D Drawing according to Figure 4A A schematic diagram of parameters ψD, ψED and d in the fourth embodiment;

[0037] Figure 4E Drawing according to Figure 4A A schematic diagram of parameter θ in the fourth embodiment; and

[0038] Figure 4F Drawing according to Figure 4A A schematic diagram of parameters h and ψs1 in the fourth embodiment.

[0039] [Symbol Explanation]

[0040] Electronic devices: 10

[0041] Camera modules: 11, 21, 31, 41

[0042] Surface flat plates: 12, 22, 32, 42

[0043] Surface glass: 121, 221, 321, 421

[0044] Backlight boards: 122, 222, 322, 422

[0045] Opening: 1221

[0046] Plastic lens barrels: 111, 211, 311, 411

[0047] External surface of the object end: 1111, 2111, 3111, 4111

[0048] External bevel at object end: 1112, 2112, 3112, 4112

[0049] Minimum aperture of the lens barrel: 1113, 2113, 3113, 4113

[0050] Back bevel: 1114, 2114, 3114, 4114

[0051] First plastic lens: 1121, 2121, 3121, 4121

[0052] Second plastic lens: 1122, 2122, 3122, 4122

[0053] Third plastic lens: 1123, 2123, 3123, 4123

[0054] Fourth plastic lens: 1124, 2124, 3124, 4124

[0055] Fifth plastic lens: 1125, 2125, 3125, 4125

[0056] Light-blocking plates: 1131, 1132, 1133, 2131, 2132, 2133, 3131, 3132, 3133, 4131, 4132, 4133

[0057] Spacer rings: 1134, 1135, 2134, 2135, 3134, 3135, 4134, 4135

[0058] Retaining rings: 1136, 2136, 3136, 4136

[0059] Imaging planes: 113, 213, 313, 413

[0060] Image sensors: 114, 214, 314, 414

[0061] Optical axis: X

[0062] h: The distance between the minimum opening of the lens barrel and the outer surface of the object end in the direction parallel to the optical axis.

[0063] d: The distance between the minimum opening of the lens barrel and the light shield in the direction parallel to the optical axis.

[0064] θ: The angle between the first and second conical surfaces through a section line passing through the optical axis.

[0065] ψD: Maximum outer diameter of the outer surface of the object end

[0066] ψED: Diameter of the minimum opening of the microscope tube

[0067] ψs1: Diameter of the opening of the light-shielding plate

[0068] g: Distance between the outer surface of the object end and the surface plate in the direction parallel to the optical axis X. Detailed Implementation

[0069] This disclosure provides a camera module including an imaging lens and an image sensor, wherein the image sensor is located on the image side of the imaging lens. The imaging lens has an optical axis and includes a plastic lens barrel and a plurality of plastic lenses, wherein the plastic lenses are disposed within the plastic lens barrel. The plastic lens barrel includes an object-end outer surface, a minimum aperture of the lens barrel, an object-end outer bevel, and a reverse bevel. The object-end outer surface is the surface of the plastic lens barrel facing the object side and closest to the object side, and is annular. The object-end outer bevel tapers from the object-end outer surface towards the minimum aperture of the lens barrel. The reverse bevel gradually expands from the minimum aperture of the lens barrel towards the image side, wherein the connection between the reverse bevel and the object-end outer bevel surrounds to form the minimum aperture of the lens barrel. The number of plastic lenses is N, the maximum outer diameter of the object end's outer surface is ψD, the distance between the minimum aperture of the lens barrel and the object end's outer surface in the direction parallel to the optical axis is h, and the principal ray angle between the principal imaging ray of the imaging lens corresponding to an image height of 1.0F and the image sensor is CRA 1.0F, which satisfies the following conditions: 4 ≤ N ≤ 10; 0.8 mm < ψD ≤ 3.4 mm; 0.01 mm < h < 0.15 mm; and CRA 1.0F > 25.0 degrees. By controlling the maximum outer diameter ψD of the object end's outer surface within a suitable range, the configuration of the minimum aperture of the lens barrel can be moved closer to the object end's outer surface, reducing the possible unnecessary reflections between the object end's outer surface and the surface plate. On the other hand, keeping h within a specific range can maintain the dimensional stability of the injection molding and the manufacturing quality of the minimum aperture of the lens barrel. Furthermore, the configuration of the object end bevel and the reverse bevel makes it less likely for the minimum aperture of the lens barrel to cause additional unexpected light reflections. This can effectively eliminate stray light phenomena that are prone to occur in camera modules with a CRA greater than a certain angle. The larger CRA makes the stray light paths near the minimum aperture of the lens barrel more consistent, making the design configuration of the reverse bevel and h more efficient in eliminating stray light.

[0070] Furthermore, a larger CRA allows the imaging lens to have an exit pupil and principal point closer to the image sensor, effectively shortening its back focal length and facilitating miniaturization despite the increasing number of lenses. In contrast, existing technologies, such as endoscopes, have relatively small CRAs and fewer lenses, making it difficult to fully utilize the advantages of a large CRA. On the other hand, the imaging lenses of larger CRAs are often too large in size and have too large an imaging surface area to be miniaturized, making them less suitable for portable electronic devices.

[0071] The imaging lens may also include a light-shielding plate, housed within the plastic lens barrel and located between the smallest opening of the lens barrel and the object-side periphery of the plastic lens closest to the object side. The design of the anti-slant surface brings the smallest opening of the lens barrel closer to the object side than the anti-slant surface itself, allowing non-imaging rays from larger incident angles to more easily enter the anti-slant surface. This makes the path of non-imaging rays easier to control, allowing for the design of a suitable light-shielding plate to achieve maximum shielding efficiency.

[0072] The distance d between the minimum opening of the lens barrel and the light-shielding plate in the direction parallel to the optical axis satisfies the following condition: 0.10 mm < d < 0.4 mm. This improves the light-shielding efficiency of the light-shielding plate in conjunction with the reverse bevel, enabling it to handle environments with higher stray light intensity. Additionally, the following condition must be met: 0.12 mm < d < 0.4 mm.

[0073] The distance between the minimum opening of the lens barrel and the light shield in the direction parallel to the optical axis is d, and the distance between the minimum opening of the lens barrel and the outer surface of the object end in the direction parallel to the optical axis is h. These distances satisfy the following condition: 1.0 < d / h < 15.0. This allows the anti-slant surface and the light shield to capture more stray light.

[0074] The maximum outer diameter of the object end's outer surface is ψD, which satisfies the following condition: 1.0 mm < ψD < 2.8 mm. This maintains the manufacturability of injection molding, ensuring good dimensional accuracy of the lens barrel molding quality when the minimum opening of the lens barrel is pushed outwards towards the object end's outer surface.

[0075] The anti-slant can contain multiple straight strip structures extending from the smallest opening in the lens barrel toward the direction perpendicular to the optical axis. In detail, the straight strip structures can be set on the surface of the anti-slant, which can increase the efficiency of the anti-slant in eliminating high-intensity non-imaging light rays. This is suitable for miniaturized imaging lenses and can further eliminate the additional reflections that occur when the surface of the light shield itself receives a large amount of stray light.

[0076] The minimum aperture diameter of the lens barrel is ψED, and the aperture diameter of the light-shielding plate is ψs1, satisfying the following condition: 0.8 ≤ ψED / ψs1 ≤ 1.05. This increases the light-shielding area of ​​the light-shielding plate without affecting the resolving power and optical specifications of the imaging lens. Additionally, the following condition can be satisfied: 0.8 ≤ ψED / ψs1 ≤ 1.0. This further reduces surface reflections from the aperture of the light-shielding plate itself.

[0077] The outer bevel of the object end can be a first conical surface, and the reverse bevel can be a second conical surface. The angle between the first and second conical surfaces through a section line passing through the optical axis is θ, satisfying the following condition: 45 degrees < θ < 120 degrees. This reduces the probability of surface reflection from the outer and reverse bevels and maintains its machinability. Specifically, machinability can be achieved by applying surface atomization, cutting, or other processing methods to the molding die corresponding to the aforementioned parts, giving the two parts better stray light elimination capabilities after molding.

[0078] The various technical features in the camera module disclosed above can be combined and configured to achieve the corresponding effects.

[0079] This disclosure provides an electronic device that can be used for photography. The electronic device includes the aforementioned camera module and a surface plate, wherein the surface plate is disposed on the object side of the camera module. The distance g between the outer surface of the object and the surface plate in the direction parallel to the optical axis satisfies the following condition: 0.03 mm < g < 0.3 mm. This prevents stray light from entering the imaging lens through unexpected paths, allowing the minimum aperture h of the lens barrel to block high-intensity light sources earlier, and enabling subsequent attenuation of stray light to be easily handled by other stray light blocking methods within the lens. Additionally, the following condition can be satisfied: 0.03 mm < g < 0.26 mm.

[0080] Additionally, the surface panel can be a tablet with a display module. More specifically, the surface panel can be a display screen, which may include a surface glass and a backlight panel, but is not limited thereto.

[0081] <First Embodiment>

[0082] Figure 1A A schematic diagram of the electronic device 10 according to the first embodiment of this disclosure is shown. Figure 1A As can be seen, the electronic device 10 is a mobile phone, and a full-screen mobile phone, but the content of this disclosure is not limited thereto. The electronic device 10 includes a camera module 11 and a surface tablet 12, wherein the surface tablet 12 is disposed on the object side of the camera module 11.

[0083] In detail, Figure 1B Drawing according to Figure 1A A schematic diagram of the surface plate 12 in the first embodiment. Figure 1C Drawing according to Figure 1A A schematic diagram of the surface plate 12 and the camera module 11 in the first embodiment. Figure 1D Drawing according to Figure 1AAnother schematic diagram of the surface plate 12 and camera module 11 in the first embodiment. As shown in Figures 1B, 1C, and 1D, the surface plate 12 can be a plate with a display function module, which may include a surface glass 121 and a backlight plate 122, wherein the backlight plate 122 is connected to the image-side surface of the surface glass 121. The surface glass 121 may be a glass substrate, and the backlight plate 122 may be an LED as the light source of the array, but the present disclosure is not limited thereto. The camera module 11 includes an imaging lens (not otherwise labeled) and an image sensor 114, wherein the image sensor 114 is located on the image side (i.e., on the imaging surface 113) of the imaging lens, and the surface plate 12 is located on the object side of the imaging lens.

[0084] The imaging lens includes a plastic lens barrel 111 and a plurality of plastic lenses, wherein the plastic lenses are disposed within the plastic lens barrel 111 and, from the object side to the image side, are a first plastic lens 1121, a second plastic lens 1122, a third plastic lens 1123, a fourth plastic lens 1124, and a fifth plastic lens 1125, respectively. Specifically, in the first embodiment, the number of plastic lenses is N, and N = 5. Furthermore, the imaging lens also includes a plurality of light-shielding plates 1131, 1132, 1133, a plurality of spacer rings 1134, 1135, and a fixing ring 1136, wherein the light-shielding plates 1131, 1132, 1133, spacer rings 1134, 1135, and fixing ring 1136 are all disposed within the plastic lens barrel 111.

[0085] Reference Figure 1E as well as Figure 1F ,in Figure 1E Drawing according to Figure 1A A schematic diagram of the plastic lens barrel 111 in the first embodiment. Figure 1F Drawing according to Figure 1A A three-dimensional schematic diagram of the plastic lens barrel 111 in the first embodiment. (From...) Figure 1E as well as Figure 1F As can be seen, the plastic lens barrel 111 includes an object-end outer surface 1111, an object-end outer bevel 1112, a minimum opening 1113, and a reverse bevel 1114. The object-end outer surface 1111 is the surface of the plastic lens barrel 111 facing the object side and closest to the object side, and is annular. The object-end outer bevel 1112 gradually tapers from the object-end outer surface 1111 towards the minimum opening 1113. The reverse bevel 1114 gradually expands from the minimum opening 1113 towards the image side, wherein the connection between the reverse bevel 1114 and the object-end outer bevel 1112 surrounds and forms the minimum opening 1113. In addition, the light shield 1131 is located between the minimum opening 1113 and the object-side periphery of the plastic lens closest to the object side (i.e., the first plastic lens 1121).

[0086] Figure 1G Drawing according to Figure 1A A schematic diagram of parameters h and d in the first embodiment. (From...) Figure 1G It can be seen that the distance between the minimum opening 1113 of the lens barrel and the outer surface 1111 of the object end in the direction parallel to the optical axis X is h, and the distance between the minimum opening 1113 of the lens barrel and the light shield 1131 in the direction parallel to the optical axis X is d, and h = 0.04 mm, d = 0.2155 mm, d / h = 5.3875.

[0087] Figure 1H Drawing according to Figure 1A A schematic diagram of parameter θ in the first embodiment. (From...) Figure 1H It can be seen that the outer inclined surface 1112 of the object end is the first conical surface (unlabeled), and the reverse inclined surface 1114 is the second conical surface (unlabeled). The angle between the first conical surface and the second conical surface through a section line passing through the optical axis X is θ, and θ = 112.63 degrees.

[0088] Figure 1I Drawing according to Figure 1A A schematic diagram of parameters ψD, ψED, and ψs1 in the first embodiment. (From...) Figure 1I It can be seen that the maximum outer diameter of the object end outer surface 1111 is ψD, the diameter of the minimum opening 1113 of the lens tube is ψED, the opening diameter of the light shield 1131 is ψs1, and ψD = 2.6 mm, ψED = 1.59 mm, ψs1 = 1.7 mm, ψED / ψs1 = 0.935.

[0089] Cooperate Figure 1C as well as Figure 1D It can be seen that the distance between the outer surface 1111 of the object end and the surface plate 12 in the direction parallel to the optical axis X is g, and g = 0.13 mm. It must be noted that the backlight plate 122 of the surface plate 12 has an opening 1221 corresponding to the imaging lens. The area of ​​the surface glass 121 corresponding to the opening 1221 is the image capture window, which is coaxial with the imaging lens to facilitate the imaging lens to capture the image. The distance between the outer surface 1111 of the object end and the surface plate 12 in the direction parallel to the optical axis X is the same as the distance between the outer surface 1111 of the object end and the image side surface of the surface glass 121 in the direction parallel to the optical axis X. In addition, the principal ray angle between the principal imaging ray of the imaging lens corresponding to the 1.0F image height and the image sensor 114 is CRA1.0F, and CRA1.0F = 33.73 degrees.

[0090] <Second Embodiment>

[0091] Figure 2A A schematic diagram illustrating the surface plate 22 and camera module 21 of the electronic device according to the second embodiment of this disclosure is shown. Figure 2AIt is known that the electronic device (unless otherwise labeled) includes a camera module 21 and a surface plate 22, wherein the surface plate 22 is disposed on the object side of the camera module 21.

[0092] In detail, Figure 2B Drawing according to Figure 2A Another schematic diagram of the surface plate 22 and camera module 21 in the second embodiment. Figure 2C Drawing according to Figure 2A Another schematic diagram of the surface plate 12 and camera module 11 in the second embodiment. As shown in Figures 2B and 2C, the surface plate 22 can be a plate with a display function module, which may include a surface glass 221 and a backlight board 222. The backlight board 222 may further include a circuit board or auxiliary components related to the backlight board. The backlight board 222 is connected to the image-side surface of the surface glass 221. The surface glass 221 may be a glass substrate, and the backlight board 222 may be an LED as the light source of the array, but this disclosure is not limited thereto. The camera module 21 includes an imaging lens (not otherwise labeled) and an image sensor 214, wherein the image sensor 214 is located on the image side (i.e., on the imaging surface 213) of the imaging lens, and the surface plate 22 is located on the object side of the imaging lens.

[0093] The imaging lens includes a plastic lens barrel 211 and multiple plastic lenses, wherein the plastic lenses are disposed within the plastic lens barrel 211 and, from the object side to the image side, are a first plastic lens 2121, a second plastic lens 2122, a third plastic lens 2123, a fourth plastic lens 2124, and a fifth plastic lens 2125, respectively. Specifically, in the second embodiment, the number of plastic lenses is N, and N = 5. Furthermore, the imaging lens also includes multiple light-shielding plates 2131, 2132, 2133, multiple spacer rings 2134, 2135, and a fixing ring 2136, wherein the light-shielding plates 2131, 2132, 2133, spacer rings 2134, 2135, and fixing ring 2136 are all disposed within the plastic lens barrel 211.

[0094] The plastic lens barrel 211 includes an object-end outer surface 2111, an object-end outer bevel 2112, a minimum opening 2113, and a reverse bevel 2114. The object-end outer surface 2111 is the surface of the plastic lens barrel 211 facing the object side and closest to the object side, and is annular. The object-end outer bevel 2112 gradually tapers from the object-end outer surface 2111 towards the minimum opening 2113. The reverse bevel 2114 gradually expands from the minimum opening 2113 towards the image side, wherein the connection between the reverse bevel 2114 and the object-end outer bevel 2112 surrounds and forms the minimum opening 2113. In addition, a light shield 2131 is located between the minimum opening 2113 and the object-side periphery of the plastic lens closest to the object side (i.e., the first plastic lens 2121).

[0095] Figure 2D Drawing according to Figure 2A A schematic diagram of parameters h and d in the second embodiment. (From...) Figure 2D It can be seen that the distance between the minimum opening 2113 of the lens barrel and the outer surface 2111 of the object end in the direction parallel to the optical axis X is h, and the distance between the minimum opening 2113 of the lens barrel and the light shield 2131 in the direction parallel to the optical axis X is d, and h = 0.1155 mm, d = 0.14 mm, d / h = 1.2121.

[0096] Figure 2E Drawing according to Figure 2A A schematic diagram of parameter θ in the second embodiment. (From...) Figure 2E It can be seen that the outer inclined surface 2112 of the object end is the first conical surface (unlabeled), and the reverse inclined surface 2114 is the second conical surface (unlabeled). The angle between the first conical surface and the second conical surface through a section line of the optical axis X is θ, and θ = 93.95 degrees.

[0097] Figure 2F Drawing according to Figure 2A A schematic diagram of parameters ψD, ψED, and ψs1 in the second embodiment. (From...) Figure 2F It can be seen that the maximum outer diameter of the object end outer surface 2111 is ψD, the diameter of the minimum opening 2113 of the lens tube is ψED, the opening diameter of the light shield 2131 is ψs1, and ψD = 2.6 mm, ψED = 1.66 mm, ψs1 = 1.7 mm, ψED / ψs1 = 0.976.

[0098] Cooperate Figure 2A as well as Figure 2C It can be seen that the distance between the outer surface 2111 of the object end and the surface plate 22 in the direction parallel to the optical axis X is g, and g = 0.2 mm. It must be noted that the backlight plate 222 of the surface plate 22 has an opening 2221 corresponding to the imaging lens. The area of ​​the surface glass 221 corresponding to the opening 2221 is the image capture window, which is coaxial with the imaging lens to facilitate the imaging lens to capture the image. The distance between the outer surface 2111 of the object end and the surface plate 22 in the direction parallel to the optical axis X is the same as the distance between the outer surface 2111 of the object end and the image side surface of the surface glass 221 in the direction parallel to the optical axis X. In addition, the principal ray angle between the principal imaging ray of the imaging lens corresponding to the 1.0F image height and the image sensor 214 is CRA 1.0F, and CRA 1.0F = 33.73 degrees.

[0099] <Third Embodiment>

[0100] Figure 3A A schematic diagram illustrating the surface plate 32 and camera module 31 of the electronic device according to the third embodiment of this disclosure is shown. Figure 3AAs can be seen, the electronic device (not otherwise labeled) includes a camera module 31 and a surface plate 32, wherein the surface plate 32 is disposed on the object side of the camera module 31. The surface plate 32 may be a plate with a display function module, and may include a surface glass 321 and a backlight plate 322, wherein the backlight plate 322 is connected to the image side surface of the surface glass 321. The surface glass 321 may be a glass substrate, and the backlight plate 322 may be an LED as the light source of the array, but this disclosure is not limited thereto. The camera module 31 includes an imaging lens (not otherwise labeled) and an image sensor 314, wherein the image sensor 314 is located on the image side of the imaging lens (i.e., on the imaging surface 313), and the surface plate 32 is located on the object side of the imaging lens.

[0101] The imaging lens includes a plastic lens barrel 311 and a plurality of plastic lenses, wherein the plastic lenses are disposed within the plastic lens barrel 311 and, from the object side to the image side, are a first plastic lens 3121, a second plastic lens 3122, a third plastic lens 3123, a fourth plastic lens 3124, and a fifth plastic lens 3125, respectively. Specifically, in the third embodiment, the number of plastic lenses is N, and N = 5. Furthermore, the imaging lens also includes a plurality of light-shielding plates 3131, 3132, 3133, a plurality of spacer rings 3134, 3135, and a fixing ring 3136, wherein the light-shielding plates 3131, 3132, 3133, spacer rings 3134, 3135, and fixing ring 3136 are all disposed within the plastic lens barrel 311.

[0102] The plastic lens barrel 311 includes an object-end outer surface 3111, an object-end outer bevel 3112, a minimum aperture 3113, and a reverse bevel 3114. The object-end outer surface 3111 is the surface of the plastic lens barrel 311 facing the object side and closest to the object side, and is annular. The object-end outer bevel 3112 gradually tapers from the object-end outer surface 3111 towards the minimum aperture 3113. The reverse bevel 3114 gradually expands from the minimum aperture 3113 towards the image side, wherein the connection between the reverse bevel 3114 and the object-end outer bevel 3112 surrounds and forms the minimum aperture 3113. In addition, a light shield 3131 is located between the minimum aperture 3113 and the object-side periphery of the plastic lens closest to the object side (i.e., the first plastic lens 3121).

[0103] Figure 3B Drawing according to Figure 3A A schematic diagram of parameters h and d in the third embodiment. (From...) Figure 3B It can be seen that the distance between the minimum opening 3113 of the lens barrel and the outer surface 3111 of the object end in the direction parallel to the optical axis X is h, and the distance between the minimum opening 3113 of the lens barrel and the light shield 3131 in the direction parallel to the optical axis X is d, and h = 0.05 mm, d = 0.215 mm, d / h = 4.3.

[0104] Figure 3C Drawing according to Figure 3A A schematic diagram of parameter θ in the third embodiment. (From...) Figure 3C It can be seen that the outer inclined surface 3112 of the object end is the first conical surface (unlabeled), and the reverse inclined surface 3114 is the second conical surface (unlabeled). The angle between the first conical surface and the second conical surface through a section line of the optical axis X is θ, and θ = 100 degrees.

[0105] Figure 3D Drawing according to Figure 3A A schematic diagram of parameters ψD, ψED, and ψs1 in the third embodiment. (From...) Figure 3D It can be seen that the maximum outer diameter of the object end outer surface 3111 is ψD, the diameter of the minimum opening 3113 of the lens tube is ψED, the opening diameter of the light shield 3131 is ψs1, and ψD = 2.1 mm, ψED = 1.68 mm, ψs1 = 1.7 mm, ψED / ψs1 = 0.988.

[0106] Depend on Figure 3A It can be seen that the distance between the outer surface 3111 of the object end and the surface plate 32 in the direction parallel to the optical axis X is g, and g = 0.25 mm. It must be noted that the backlight plate 322 of the surface plate 32 has an opening 3221 corresponding to the imaging lens. The area of ​​the surface glass 321 corresponding to the opening 3221 is the image-capturing window, which is coaxial with the imaging lens to facilitate image capture. The distance between the outer surface 3111 of the object end and the surface plate 32 in the direction parallel to the optical axis X is the same as the distance between the outer surface 3111 of the object end and the image-side surface of the surface glass 321 in the direction parallel to the optical axis X. Furthermore, the principal ray angle between the principal imaging ray of the imaging lens corresponding to an image height of 1.0F and the image sensor 314 is CRA 1.0F, and CRA 1.0F = 33.73 degrees.

[0107] <Fourth Embodiment>

[0108] Figure 4A A schematic diagram illustrating the surface plate 42 and camera module 41 of the electronic device according to the fourth embodiment of this disclosure is shown. Figure 4AAs can be seen, the electronic device (not otherwise labeled) includes a camera module 41 and a surface plate 42, wherein the surface plate 42 is disposed on the object side of the camera module 41. The surface plate 42 may be a plate with a display function module, and may include a surface glass 421 and a backlight plate 422, wherein the backlight plate 422 is connected to the image side surface of the surface glass 421. The surface glass 421 may be a glass substrate, and the backlight plate 422 may be an LED as the light source of the array, but this disclosure is not limited thereto. The camera module 41 includes an imaging lens (not otherwise labeled) and an image sensor 414, wherein the image sensor 414 is located on the image side (i.e., on the imaging surface 413) of the imaging lens, and the surface plate 42 is located on the object side of the imaging lens.

[0109] Reference Figure 4B It is a drawing based on Figure 4A An exploded view of the imaging lens in the fourth embodiment. Figure 4A as well as Figure 4B As can be seen, the imaging lens includes a plastic lens barrel 411 and multiple plastic lenses, wherein the plastic lenses are disposed within the plastic lens barrel 411, and from the object side to the image side are a first plastic lens 4121, a second plastic lens 4122, a third plastic lens 4123, a fourth plastic lens 4124, and a fifth plastic lens 4125, respectively. Specifically, in the fourth embodiment, the number of plastic lenses is N, and N = 5. Furthermore, the imaging lens also includes multiple light-shielding plates 4131, 4132, 4133, multiple spacer rings 4134, 4135, and a fixing ring 4136, wherein the light-shielding plates 4131, 4132, 4133, spacer rings 4134, 4135, and fixing ring 4136 are all disposed within the plastic lens barrel 411.

[0110] Reference Figure 4C It is a drawing based on Figure 4A A three-dimensional schematic diagram of the plastic lens barrel 411 in the fourth embodiment. Figure 4C It is known that the plastic lens barrel 411 includes an object-end outer surface 4111, an object-end outer bevel 4112, a minimum opening 4113, and a reverse bevel 4114. The object-end outer surface 4111 is the surface of the plastic lens barrel 411 facing the object side and closest to the object side, and is annular. The object-end outer bevel 4112 gradually tapers from the object-end outer surface 4111 towards the minimum opening 4113. The reverse bevel 4114 gradually expands from the minimum opening 4113 towards the image side, wherein the connection between the reverse bevel 4114 and the object-end outer bevel 4112 surrounds and forms the minimum opening 4113. In addition, the light shield 4131 is located between the minimum opening 4113 and the object-side periphery of the plastic lens closest to the object side (i.e., the first plastic lens 4121).

[0111] Furthermore, the anti-sloping surface 4114 includes a plurality of straight strip structures 4115 extending from the minimum opening 4113 of the lens barrel in a direction perpendicular to the optical axis X. In detail, in the fourth embodiment, the straight strip structures 4115 are wedge-shaped structures, numbering 320, and gradually tapering linearly from the anti-sloping surface 4114 toward the optical axis X.

[0112] Figure 4D Drawing according to Figure 4A A schematic diagram of parameters ψD, ψED and d in the fourth embodiment. Figure 4E Drawing according to Figure 4A A schematic diagram of parameter θ in the fourth embodiment. Figure 4F Drawing according to Figure 4A A schematic diagram of parameters h and ψs1 in the fourth embodiment. Figure 4D , Figure 4E as well as Figure 4F It can be seen that the distance between the minimum opening 4113 of the lens barrel and the outer surface 4111 of the object end in the direction parallel to the optical axis X is h, and the distance between the minimum opening 4113 of the lens barrel and the light-shielding plate 4131 in the direction parallel to the optical axis X is d, where h = 0.04 mm, d = 0.2155 mm, and d / h = 5.3875. The outer inclined surface 4112 of the object end is the first conical surface (unlabeled), and the reverse inclined surface 4114 is the second conical surface (unlabeled). The angle between the first conical surface and the second conical surface through a section line passing through the optical axis X is θ, and θ = 112.63 degrees. The maximum outer diameter of the object end outer surface 4111 is ψD, the diameter of the minimum opening 4113 of the lens tube is ψED, the opening diameter of the light shield 4131 is ψs1, and ψD = 2.6 mm, ψED = 1.59 mm, ψs1 = 1.7 mm, ψED / ψs1 = 0.935.

[0113] Depend on Figure 4A It can be seen that the distance between the outer surface 4111 of the object end and the surface plate 42 in the direction parallel to the optical axis X is g, and g = 0.2 mm. It must be noted that the backlight plate 422 of the surface plate 42 has an opening 4221 corresponding to the imaging lens. The area of ​​the surface glass 421 corresponding to the opening 4221 is the image capture window, which is coaxial with the imaging lens to facilitate the imaging lens to capture the image. The distance between the outer surface 4111 of the object end and the surface plate 42 in the direction parallel to the optical axis X is the same as the distance between the outer surface 4111 of the object end and the image side surface of the surface glass 421 in the direction parallel to the optical axis X. In addition, the principal ray angle between the principal imaging ray of the imaging lens corresponding to the 1.0F image height and the image sensor 414 is CRA 1.0F, and CRA1.0F = 33.73 degrees.

[0114] Although the present disclosure has been presented above with reference to embodiments, it is not intended to limit the scope of the present disclosure. Anyone skilled in the art may make some modifications and refinements without departing from the spirit and scope of the present disclosure. Therefore, the scope of protection of the present disclosure shall be determined by the scope defined in the appended claims.

Claims

1. A camera module, characterized in that, It includes an imaging lens and an image sensor, wherein the image sensor is located on the image side of the imaging lens, and the imaging lens has an optical axis and includes: A plastic lens barrel, comprising: The outer surface of the object end is the surface of the plastic lens barrel facing the object side and closest to the object side, and it is annular; The smallest opening in a lens barrel; The outer bevel of the object end gradually narrows from the outer surface of the object end toward the smallest opening of the lens tube. as well as A reverse bevel gradually expands from the minimum opening of the lens barrel toward the image side, wherein the connection between the reverse bevel and the outer bevel of the object end surrounds and forms the minimum opening of the lens barrel. Multiple plastic lenses are disposed within the plastic lens barrel; and A light-shielding plate is installed inside the plastic lens barrel; Wherein, the number of the plurality of plastic lenses is N, the distance between the minimum opening of the lens barrel and the light shield in the direction parallel to the optical axis is d, the distance between the minimum opening of the lens barrel and the outer surface of the object end in the direction parallel to the optical axis is h, the diameter of the minimum opening of the lens barrel is ψED, the diameter of the opening of the light shield is ψs1, and the principal ray angle between a principal imaging ray of the imaging lens corresponding to an image height of 1.0F and the image sensor is CRA 1.0F, which satisfies the following conditions: 4 ≤ N ≤ 10; 1.0 < d / h < 15.0; 0.8 ≤ ψED / ψs1 ≤ 1.05; and CRA 1.0F > 25.0 degrees.

2. The camera module according to claim 1, characterized in that, The light-shielding plate is located between the smallest opening of the lens barrel and the object-side peripheral portion of the one of the plurality of plastic lenses closest to the object side.

3. The camera module according to claim 1, characterized in that, The anti-sloping surface comprises multiple straight strip-shaped structures that extend from the smallest opening of the lens barrel in a direction perpendicular to the optical axis.

4. The camera module according to claim 1, characterized in that, The minimum opening diameter of the lens barrel is ψED, and the opening diameter of the light-shielding plate is ψs1, which satisfy the following conditions: 0.8 ≤ ψED / ψs1 ≤ 1.

0.

5. The camera module according to claim 1, characterized in that, The outer inclined surface of the object is a first conical surface, and the reverse inclined surface is a second conical surface. The angle between the first conical surface and the second conical surface through a section line passing through the optical axis is θ, and they satisfy the following conditions: 45 degrees < θ < 120 degrees.

6. An electronic device, characterized in that, Include: The camera module as claimed in claim 1; and A flat surface is disposed on the object side of the camera module; Wherein, the distance g between the outer surface of the object end and the surface plate in the direction parallel to the optical axis satisfies the following condition: 0.03 mm < g < 0.3 mm.

7. The electronic device according to claim 6, characterized in that, The surface plate is a flat plate with a display function module.