CN218524939U - Miniaturized imaging system - Google Patents

Abstract

A miniaturized imaging system comprises an infrared incidence unit, a reflection unit and an infrared imaging device which are sequentially arranged along a light path; the infrared incidence unit comprises an incidence lens and a first lens fixing frame for fixing the incidence lens; the reflecting unit comprises a reflecting mirror and a second mirror fixing frame used for fixing the reflecting mirror. This application can effectively change light propagation path, and the reinforcing sees through light intensity, makes formation of image reach the anticipated effect of similar tradition installing optical window at the aircraft front end.

Description

Miniaturized imaging system

Technical Field

The utility model belongs to the technical field of the formation of image, especially, relate to a miniaturized imaging system.

Background

The infrared optical window detection can be widely considered as that invisible infrared radiant energy of a target and a background is received by a detector, is converted into a visible image by photoelectric conversion, and the difference of infrared radiant characteristics between the target and the background is compared according to the difference of temperatures of the target and the background, so that the image is distinguished, and the value target to be observed is found or the target is prevented from being found. The imaging technology can be applied to various detection scenes, such as space-based detection, foundation detection, recently developed near space-based detection, infrared guidance carried on an aircraft and the like. After the second war, the United states firstly applies the infrared technology to national defense and military, carries an infrared detection system on a man-made satellite, realizes real-time detection on a high-speed aircraft, and sequentially transmits a plurality of satellites to form an SBIRS space-based early warning system.

The self-infrared imaging technology is applied to various high-speed aircrafts, and reliable high-quality images are always the focus of attention of students as the front end of a target information source. In a high-speed flight environment, an optical window can deform due to a complex thermal environment, so that structural deformation or functional failure is caused; the problems of aberration, distortion and the like can also be caused in the acquisition under the action of the pneumatic thermal effect, and the imaging quality is seriously threatened. When the performance and the process of the infrared detector reach certain bottlenecks, students often design and verify the performance of an imaging system through a numerical simulation and semi-physical simulation platform, and accordingly research the stable and reliable imaging problem of the infrared system of the high-speed aircraft.

The method aims at the problems that an infrared optical window on a high-speed aircraft can generate non-uniform temperature distribution and deformation due to a complex aerodynamic thermal environment, an imaging system easily generates severe aberration, imaging quality and detection precision are affected, and the like, and the design of the imaging method is widely researched at home and abroad. Generally, in order to facilitate detection imaging, most of infrared windows of this type are deployed at the front end of a high-speed aircraft, and the research on reliable imaging methods mostly focuses on the aspects of thermal effect mechanisms, flow field force-heat characteristic prediction calculation, window thermal response analysis, window refractive index, light ray tracing, structural deformation and the like. With the intensive research, people find that the conformal window has better light transmission characteristics than a planar window with respect to imaging quality and the light transmission effect of an outflowing field, and generally, the temperature of the front end of an aircraft is highest, and the temperature is gradually reduced from a stagnation point to the bottom end; in this regard, mounting the optical window on the side of the seeker reduces the effect of the complex thermal environment on imaging. However, mounting the optical window on the side of the aircraft presents a difficult problem in designing the imaging method, and the problems of light transmittance and light intensity under the influence of a large incident angle, as well as the practical problems of spatial layout, light path deflection and the like must be considered.

The starting point of the design of the deflection light path is to change the propagation direction of a light beam or adjust the imaging visual axis, and the design can be divided into the following steps according to different physical principles: mechanical light deflection technology, micro-electro mechanical Systems (mems) light deflection technology, and non-mechanical light deflection technology.

The mechanical light deflection system generally controls the spatial position change of a reflector and a transmission mirror through an inertia mechanical part to change the incident angle of a light beam so as to achieve the purpose of light path deflection; or the coaxial independent rotation of a rotating prism (double-wedge, risley prism and the like) is used for changing the emergent direction of the light beam so as to adjust the visual axis pointing. The basic principle of the mems-based light deflection technology is that a rotatable micromirror surface is rotated or translated by magnetic force or static electricity, so as to change the propagation direction of incident light, and the technique can be classified into modes of an electrostatic driving micromirror, a piezoelectric driving micromirror, an electrothermal driving micromirror, an electromagnetic driving micromirror, and the like. The non-mechanical light deflection technology is to control the phase distribution of the emergent light beam by controlling the acousto-optic effect, the electro-optic effect and the like to change the refractive index of a medium through which the incident light beam passes, thereby realizing the deflection of the emergent light beam, and can be divided into an acousto-optic modulation mode and an electro-optic modulation mode.

Generally, key devices in a mechanical light deflection system are inertial mechanical elements, an optical imaging mirror and the like, which can realize large-angle deflection and low economic cost, but generally have large volume and weight. The micro-electromechanical light deflection technology has the advantages of higher required driving voltage, complex preparation, smaller deflection angle (generally less than 10 degrees), and limited application range. The non-mechanical light deflection technology is typically applied to liquid crystal gratings, can realize large-angle deflection of light beams, and has high energy efficiency and low driving voltage, but components are fine, the manufacturing difficulty is high, and the economic cost is high.

SUMMERY OF THE UTILITY MODEL

In view of the above background, the present patent provides a miniaturized imaging system, which can well consider the problems of large incident angle and spatial dimension, and realize stable imaging through light path deflection. The specific scheme is as follows:

a miniaturized imaging system comprises an infrared incidence unit, a reflection unit, an infrared imaging device and a supporting component which are sequentially arranged along a light path; the infrared incidence unit comprises an incidence lens and a first lens fixing frame for fixing the incidence lens; the reflection unit includes speculum and the second lens mount that is used for fixed reflector, supporting component is including the first backup pad that is located infrared imaging device below, first backup pad below still is fixed with the switching bottom plate, the setting of second lens mount is in the side of switching bottom plate, the switching bottom plate passes through the support and presses in the second backup pad, first lens mount sets up at second backup pad side, the height-adjustable of support.

Specifically, the incident lens is sapphire.

Specifically, the incident lens is of a heterosexual structure.

Specifically, the reflector is made of quartz glass, and a reflecting surface is plated with a total reflection silver film with a medium-wave infrared reflectivity of not less than 98%.

Specifically, included angles between the first lens fixing frame and the second lens fixing frame and the corresponding switching bottom plate and included angles between the first lens fixing frame and the second lens fixing frame and the side edges of the second supporting plate are adjustable.

Specifically, grooves for placing corresponding lenses are formed in the first lens fixing frame and the second lens fixing frame, and the lenses are pressed in the grooves through pressing blocks.

Specifically, the system further comprises a shell for enclosing the infrared incidence unit, the reflection unit and the infrared imaging device, wherein the shell is a side surface formed by the first lens fixing frame, and the bottom of the shell is provided with a second supporting plate.

The beneficial effects of the utility model reside in that:

(1) The side window opening mode is adopted, the optical imaging system is installed at a relatively safe position, and the influence of the pneumatic thermal environment can be effectively reduced; accordingly, the installation and deployment position needs to consider the problem of reliable imaging, the incident direction of the light beam is approximately along the flight direction of the aircraft, and the system can effectively change the light propagation path, enhance the intensity of the transmitted light and enable the imaging to achieve the expected effect similar to the traditional method of installing an optical window at the front end of the aircraft.

(2) Sapphire is suitable for use in the near infrared band in the 1.2-8 μm region. Because the sapphire material has the characteristic of low density (the density of the sapphire material is half of that of a germanium material or a zinc selenide material), the sapphire material is particularly suitable for occasions sensitive to weight requirements, particularly for the application in a 3-5um wave band. Can ensure the transmittance and hardness of infrared light and high temperature resistance requirements.

(3) The included angles of the first lens fixing frame and the second lens fixing frame with the corresponding switching bottom plate and the side edge of the second supporting plate are adjustable, and the infrared light beams at different angles can be received on the basis that the angles of the infrared imaging device are not adjusted.

(4) The corresponding lens of location that the setting of recess and briquetting can be better.

(5) The light path with the large incident angle is satisfied, the incident light angle range is 65-85 degrees, the light path with the large incident angle has the capability of adapting to and overcoming low-intensity light, the light entering angle can reach 50-70 degrees by adjusting the installation angle of the lens, and the light transmittance of the light reaches 40-50 percent.

(6) The system has small space building capacity, can realize imaging effect in a limited space, and the light path design space of the system is not more than 300mm of cubic space.

Drawings

FIG. 1 is a schematic diagram of a system architecture;

FIG. 2 is a graph of the spectral transmittance of a silicon material.

1. An infrared incidence unit; 11. an incident lens; 12. a first lens holder; 21. a mirror; 22. a second lens holder; 3. a support frame; 4. a light beam receiving lens; 5. an infrared imaging device; 51. a supporting seat; 61. a first support plate; 62. a transfer base plate; 63. a support; 64. a second support plate.

Detailed Description

As shown in fig. 1-2, a miniaturized imaging system includes an infrared incidence unit 1, a reflection unit, an infrared imaging device 5, and a support assembly, which are sequentially disposed along an optical path; the infrared incidence unit 1 comprises an incidence lens 11 and a first lens fixing frame 12 for fixing the incidence lens 11; the reflecting unit includes a reflecting mirror 21 and a second lens holder 22 for holding the reflecting mirror 21.

The incident lens 11 is sapphire. The sapphire is plated with a film, the spectral range of the film is 3.0-5.0 mu m, the surface flatness is lambda/2, and the hundred degree tolerance is +/-0.3 mm. Specifically, the incident lens 11 has a different structure. The incident lens 11 is of an anisotropic structure and can adapt to the asymmetry of the size of a view field, and the starting point of the light path design is the opening of a side window and oblique front observation; also considering processing and device adaptation issues, the window, mirror 21 is designed as a trapezoid, as distinguished from a conventional rectangular or circular surface. Wherein the spectral transmittance curve of the sapphire material is shown in fig. 2.

The reflector 21 is made of quartz glass, and a reflecting surface is plated with a total reflection silver film with a medium wave infrared reflectivity not less than 98%.

The field angle of a detector in the infrared imaging device 5 is +/-10 degrees +/-18 degrees, the focal length is 14.8mm, the F number is 2, the field angle corresponding to each pixel is 1, and the pixel corresponding to a 10km high-altitude 15m target is 1.5. The device has the capability of remote detection imaging; through theoretical calculation, the target resolution ratio less than or equal to 15m outside 10km can be met.

The supporting component comprises a first supporting plate 61 located below the infrared imaging device 5, a switching bottom plate 62 is further fixed below the first supporting plate 61, the second lens fixing frame 22 is arranged on the side face of the switching bottom plate 62, the switching bottom plate 62 is pressed on the second supporting plate 64 through a support 63, and the first lens fixing frame 12 is arranged on the side edge of the second supporting plate 64. The first supporting plate 61 and the infrared imaging device 5 are independently installed, so that the adjustment of the tiny angle and/or position of the infrared imaging device 5 can be facilitated, and the better alignment can be realized. The support is adjustable, thus being suitable for more light angles. In order to ensure that the system is subjected to a temperature of 350 ℃ in use, the time is not less than 2min. During this period, the internal lens and mirror 21 are not deformed, ensuring proper operation, and the system further comprises a housing having one side formed by the first lens holder 12, the bottom of which is a second support plate 64, and the other side of which encloses all other components of the system. And a fire-proof heat-insulating material is pasted inside the shell and used for isolating the adverse effect of external high temperature on the optical components of the system. In this case, an asbestos plate was used.

Preferably, the included angles between the first lens holder 12 and the second lens holder 22 and the corresponding side edges of the adapting bottom plate 62 and the second supporting plate 64 are adjustable. The infrared beams of different angles can be received without adjusting the angle of the infrared imaging device 5. The supporting component further comprises a supporting frame 3, the second lens fixing frame 22 is hinged to the supporting frame 3, the center of the hole in the hinged central axis coincides with the center of the hole in the supporting frame 3, the light beam receiving lens 4 in the hole in the infrared imaging device 5 deepens into the hole, the central axis of the light beam receiving lens 4 coincides with the center of the hole, and the light beam receiving lens 4 is in supporting connection with the infrared imaging device 5 through a supporting seat 51. The bottom of the supporting seat 51 is fixed on the adapter base plate 62.

The first lens fixing frame 12 and the second lens fixing frame 22 are provided with grooves for placing corresponding lenses, and the lenses are pressed in the grooves through pressing blocks. The corresponding lens of location that the setting of recess and briquetting can be better.

The system puts high requirements on the precision of an optical imaging part, and the resolution index of an imaging mirror reaches 640 multiplied by 512@15 mu m, so that the precision of related parts of the design and processing system must be ensured. The structural design and material selection are based on lightness, precision, stability and firmness, and the main body is made of duralumin. The relation between tolerance and precision is considered in assembly, and the mounting precision is guaranteed.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. A miniaturized imaging system is characterized by comprising an infrared incidence unit (1), a reflection unit, an infrared imaging device (5) and a supporting component, wherein the infrared incidence unit, the reflection unit and the infrared imaging device are sequentially arranged along a light path; the infrared incidence unit (1) comprises an incidence lens (11) and a first lens fixing frame (12) for fixing the incidence lens (11); the reflecting unit includes speculum (21) and second lens mount (22) that are used for fixed speculum (21), the supporting component is including first backup pad (61) that is located infrared imaging device (5) below, first backup pad (61) below still is fixed with switching bottom plate (62), second lens mount (22) set up the side of switching bottom plate (62), switching bottom plate (62) are pressed on second backup pad (64) through support (63), first lens mount (12) set up in second backup pad (64) side, the height-adjustable of support (63).

2. A miniaturized imaging system according to claim 1, characterized in that said entrance lens (11) is sapphire.

3. A miniaturized imaging system according to claim 1 or 2, characterized in that said entrance lens (11) is of anisotropic structure.

4. A miniaturized imaging system according to claim 1, characterized in that the material of said mirror (21) is quartz glass, and the reflecting surface is coated with a total reflection silver film having a medium wave infrared reflectance of not less than 98%.

5. A miniaturized imaging system according to claim 1, characterized in that the first lens holder (12) and the second lens holder (22) are adjustable in angle with the corresponding adapter base plate (62) and the second support plate (64).

6. A miniaturized imaging system according to claim 1, characterized in that said first (12) and second (22) lens holders are provided with grooves for placing corresponding lenses, said lenses being pressed in the grooves by means of a pressing block.

7. A miniaturized imaging system according to claim 1, characterized in that the system further comprises a housing enclosing the infrared entrance unit (1), the reflection unit, the infrared imaging device (5), said housing being formed by a side of the first lens holder (12), the bottom of the housing being a second support plate (64).

Images