阅读说明：本技术 一种基于数字表面的电磁隐身玻璃 (Electromagnetic stealth glass based on digital surface ) 是由 戚开南 邓浩川 汪勇峰 于 2019-11-12 设计创作，主要内容包括：本发明涉及一种基于数字表面的电磁隐身玻璃,包括刻蚀ITO层、玻璃层和ITO层,玻璃层固连在刻蚀ITO层内侧面,ITO层固连在玻璃层内侧面,刻蚀ITO层上刻蚀有若干组子阵,单组所述子阵内包括若干个相同大小的方环单元,不同组所述子阵之间的方环单元大小不同,本发明具有既能实现电磁隐身、又能保证光学透明的优点。(The invention relates to electromagnetic stealth glass based on a digital surface, which comprises an etched ITO layer, a glass layer and an ITO layer, wherein the glass layer is fixedly connected with the inner side surface of the etched ITO layer, the ITO layer is fixedly connected with the inner side surface of the glass layer, a plurality of groups of subarrays are etched on the etched ITO layer, a single group of subarrays comprise a plurality of square ring units with the same size, and the square ring units among different groups of subarrays are different in size.)

1. The utility model provides an electromagnetism stealthy glass based on digital surface which characterized in that: including sculpture ITO layer (1), glass layer (2) and ITO layer (3), glass layer (2) link firmly at sculpture ITO layer (1) medial surface, and ITO layer (3) link firmly at glass layer (2) medial surface, and the sculpture has a plurality of groups subarrays on sculpture ITO layer (1), singly organize including the square ring unit of the same size of a plurality of in the subarray, different groups square ring unit size difference between the subarray.

2. The electromagnetic cloaking glass based on digital surface as claimed in claim 1, wherein: the sub-arrays are square, the total side lengths of the sub-arrays in different groups are the same, and the sub-arrays in different groups are arranged in a matrix form.

3. The electromagnetic cloaking glass based on digital surface as claimed in claim 2 wherein: a single group of the subarrays comprises 6 x 6 square ring units, and the distances among the square ring units are the same.

4. The electromagnetic cloaking glass based on digital surface as claimed in claim 3 wherein: the side length range of the square ring units is 1.6-4.8 mm, and the width of each square ring unit is 0.3 mm.

5. The electromagnetic cloaking glass based on digital surface as claimed in claim 4 wherein: the arrangement density of the square ring units on the two sides of the glass is greater than that of the square ring units in the middle of the glass.

6. The electromagnetic cloaking glass based on digital surface as claimed in claim 1, wherein: the glass layer (2) is high borosilicate glass, the dielectric constant of the glass layer is 4, and the thickness of the glass layer is 2-4 mm.

7. The electromagnetic cloaking glass based on digital surface as claimed in claim 1, wherein: the thickness of the etched ITO layer (1) is the same as that of the etched ITO layer (3), and the thickness range is 100 nm-200 nm.

Technical Field

The invention relates to the technical field of electromagnetic stealth, in particular to electromagnetic stealth glass based on a digital surface.

Background

With the rapid development of radar detection technology, stealth performance has become one of the most important technical indexes of weaponry. Cabin windshield glass is used as an essential component of weapon systems such as fighters, helicopters and ground combat vehicles, and hidden design work of the cabin windshield glass is very challenging on the premise of ensuring optical transparency. At present, ITO (indium tin oxide) coating technology is generally adopted, so that glass presents optical transparency and electromagnetic shielding effects, and the purpose of stealth is achieved by utilizing the low scattering appearance of windshield glass. However, not all windshields have a low scattering profile, and the ITO coating effect is not as pronounced. In order to further reduce the scattering of the windscreen, a wave absorbing material approach must be considered. Common wave-absorbing materials are dark, and the light transmittance of the glass is seriously influenced; the invisible design on the premise of not influencing the light transmission of the glass becomes the key for solving the problem.

Therefore, in view of the above disadvantages, it is desirable to provide an electromagnetic cloaking glass based on digital surface.

Disclosure of Invention

Technical problem to be solved

The invention aims to solve the technical problem that the electromagnetic stealth is realized, and the optical transparency is not influenced.

(II) technical scheme

In order to solve the technical problem, the invention provides electromagnetic stealth glass based on a digital surface, which comprises an etched ITO layer, a glass layer and an ITO layer, wherein the glass layer is fixedly connected with the inner side surface of the etched ITO layer, the ITO layer is fixedly connected with the inner side surface of the glass layer, a plurality of groups of sub-arrays are etched on the etched ITO layer, each group of sub-arrays comprises a plurality of square ring units with the same size, and the square ring units among the sub-arrays in different groups are different in size.

By adopting the technical scheme, a plurality of groups of square ring units are arranged, and multivariate destructive interference is utilized, so that the problem that RCS reduction amplitude and bandwidth are limited due to fixed unit quantity and phase difference of a traditional opposite phase cancellation method and a coding metamaterial is effectively solved, different square ring units generate different reflected waves, different reflected phases are mutually superposed and offset, backward echo energy is reduced, a stealth effect is generated, and glass is ensured to have excellent transparency by a mode of coating a film outside a glass layer.

As a further description of the present invention, preferably, the sub-arrays are square, the total side lengths of different groups of the sub-arrays are the same, and the different groups of the sub-arrays are arranged in a matrix form.

By adopting the technical scheme, each subarray has a proper reflection phase, and the reflection arrays can generate specific phase distribution to generate high-directivity wave beams, so that destructive interference on specific electromagnetic waves is realized.

As a further description of the present invention, it is preferable that a single group of the subarrays includes 6 × 6 square ring units, and the square ring units are spaced at the same interval.

By adopting the technical scheme, the array comprehensive theory can be utilized to optimize and obtain the arrangement positions of the subarrays which contain different square ring unit subarrays, so that the optimal RCS reduction effect is obtained.

As a further description of the present invention, preferably, the side length of the square ring unit ranges from 1.6mm to 4.8mm, and the width of the square ring unit is 0.3 mm.

By adopting the technical scheme, the electromagnetic wave between the X wave band and the Ku wave band can deviate backwards to the greatest extent, so that the echo energy of the electromagnetic wave in more frequency ranges can be reduced, and the practicability of the stealth glass is improved.

As a further explanation of the present invention, it is preferable that the arrangement density of the square ring units on both sides of the glass is greater than that of the square ring units in the middle of the glass.

By adopting the technical scheme, the cabin windshield glass of the aircraft is larger than the receiving surface of electromagnetic waves due to the arc-shaped surface, and the reflection of the electromagnetic waves from the large receiving surface can be effectively counteracted by increasing the arrangement density of square ring units on the two sides of the windshield glass, so that the stealth performance is improved.

As a further explanation of the present invention, it is preferable that the glass layer is a high borosilicate glass having a dielectric constant of 4 and a thickness of 2mm to 4 mm.

By adopting the technical scheme, the glass not only can keep good transparency, but also has excellent wave-transmitting performance.

As a further explanation of the present invention, it is preferable that the etched ITO layer has the same thickness as the ITO layer, and the thickness range is 100nm to 200 nm.

By adopting the technical scheme, the electromagnetic waves penetrate through the glass as far as possible, the outward reflection amount of the electromagnetic waves is reduced, the generated reflected electromagnetic waves can be counteracted under the mutual reflection of the square ring units, the echo energy of the electromagnetic waves is greatly weakened, and the stealth performance of the glass is improved.

(III) advantageous effects

The technical scheme of the invention has the following advantages:

the invention is developed by using common high-silicon glass as a carrier, utilizing a design method of a digital super surface and adopting an etching processing technology of an ITO film, and can have a good stealth effect in a wider electromagnetic frequency band.

Drawings

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a structural view of an etched ITO layer surface according to the present invention;

fig. 3 is a graph of the reflectivity of electromagnetic waves according to the present invention.

In the figure: 1. etching the ITO layer; 2. a glass layer; 3. an ITO layer.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

The utility model provides an electromagnetism stealthy glass based on digital surface, as shown in figure 1, includes sculpture ITO layer 1, glass layer 2 and ITO layer 3, and glass layer 2 links firmly at sculpture ITO in situ side 1, and ITO layer 3 links firmly at 2 medial surfaces of glass layer.

Combining the graph 1 and the graph 2, the material of the etched ITO layer 1 is the same as that of the etched ITO layer 3, the thickness of the etched ITO layer is also the same, and the thickness range of the etched ITO layer 1 is 100 nm-200 nm; etching a plurality of groups of sub-arrays on an ITO layer 1, wherein the sub-arrays are square, the total side lengths of the sub-arrays in different groups are the same, the sub-arrays in different groups are arranged in a matrix form, a single group of the sub-arrays comprises 6 multiplied by 6 square ring units, the intervals between the square ring units are the same, the sizes of the square ring units in different groups of the sub-arrays are different, the side length range of the square ring units is 1.6 mm-4.8 mm, and the widths of the square ring units are 0.3 mm; each subarray has a proper reflection phase, and the reflection arrays can generate specific phase distribution to generate high-directivity wave beams, so that destructive interference on specific electromagnetic waves is realized.

With reference to FIG. 1 and FIG. 2, during production, a layer of ITO film is coated on both the upper and lower surfaces of the glass layer 2, with a thickness of 100 and 200 nm; and then etching the square ring unit on the etched ITO layer 1 by using laser, wherein the ITO layer 3 is not processed.

By combining the figure 3, through corresponding calculation of electromagnetic waves of different frequency bands, the mutual arrangement positions of the proper square ring units are designed, the electromagnetic waves between an X wave band and a Ku wave band (8-18 GHz) can be reflected to the maximum extent, the electromagnetic waves can penetrate through glass as far as possible, the outward reflection amount of the electromagnetic waves is reduced, the reflected electromagnetic waves can utilize multivariate destructive interference (the reflected waves of various units are superposed in space, the non-fixed phase difference between the units increases the freedom of phase control so as to realize ultra wide band destructive interference), the arrangement positions of different subarrays containing different square ring units are obtained by utilizing array comprehensive theory optimization, so that the optimal RCS reduction effect is obtained, the problem that the RCS reduction amplitude and bandwidth are limited by the fixed unit number and the phase difference of the traditional phase inversion cancellation method and the encoding metamaterial is effectively solved, and different square ring units generate different reflected waves, different reflection phases are mutually superposed and offset, so that backward echo energy is reduced, the reflectivity of electromagnetic waves finally reflected to the outside is lower than-10 dB, a stealth effect is generated, and the glass is ensured to have excellent transparency by a mode of coating a film outside the glass layer.

With reference to fig. 1 and 2, the arrangement density of the square ring units on the two sides of the glass is greater than that of the square ring units in the middle of the glass, so that the receiving surface of electromagnetic waves is larger for the aircraft cabin windshield glass due to the arc-shaped surface, and the reflection of the electromagnetic waves from the large receiving surface can be effectively counteracted by increasing the arrangement density of the square ring units on the two sides of the windshield glass, thereby improving the stealth performance.

As shown in fig. 1, the glass layer 2 is high borosilicate glass, the dielectric constant of the glass layer is 4, and the thickness of the glass layer is 2 mm-4 mm, so that the glass not only can maintain good transparency, but also has excellent wave-transmitting performance; and absorbs electromagnetic waves as much as possible, thereby further reducing the echo energy.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.