Multi-dimensional adjustable window type camera mounting bracket and system

By using a multi-dimensional adjustable window-mounted camera bracket with flexible corrugated tubes and magnetic interfaces, the problems of fixed camera angles and glass reflections in traditional cameras are solved, enabling flexible adjustment of camera angles and improved night vision.

CN122340360APending Publication Date: 2026-07-0370MAI CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
70MAI CO LTD
Filing Date
2026-04-22
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Traditional window-mounted cameras have fixed angles and glass reflections interfere with night vision. Existing improvement solutions cannot flexibly adjust the angle and effectively block indoor light reflections.

Method used

A multi-dimensional adjustable window-mounted camera bracket is used, which utilizes flexible corrugated tubes to stretch, compress, and deflect in three-dimensional space. Combined with a magnetic interface, it can quickly connect to the camera to form a sealed cavity that blocks indoor light.

Benefits of technology

It enables flexible adjustment of the camera angle, avoids interference from glass reflections, and improves night vision imaging quality and system applicability.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN122340360A_ABST
    Figure CN122340360A_ABST
Patent Text Reader

Abstract

This application discloses a multi-dimensional adjustable window-mounted camera bracket and system. The bracket includes: a base, attached to the inner side of a transparent medium, with a light-transmitting hole in the center; a flexible corrugated tube, connected at one end to the base and at the other end to the camera interface, composed of multiple continuously arranged elastic pleats, which can be stretched, compressed, and deflected in three-dimensional space under external force; the other end of the flexible corrugated tube also has a magnetic interface with a built-in magnetic attraction element for quick connection with the camera body to form a sealed cavity. This application utilizes the multi-degree-of-freedom deformation capability of the flexible corrugated tube to achieve arbitrary adjustment of the shooting angle, and blocks ambient light interference through the formed sealed cavity, solving the problems of fixed viewing angle and glass reflection interference in imaging in traditional window-mounted brackets.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application belongs to the field of camera installation technology, specifically relating to a multi-dimensional adjustable window-mounted camera mounting bracket and system. Background Technology

[0002] Traditional window-mounted cameras typically use a fixed base and double-sided adhesive to attach to the glass. While this method is simple to install, the lens's field of view is limited to the glass surface, allowing only a horizontal outward view. Existing improvements often use fixed-angle wedge brackets, which cannot flexibly adjust the angle during use (e.g., looking down from the second floor to the first floor, or observing a corridor from the side). Furthermore, with existing brackets, when the lens is far from the glass, indoor light easily reflects off the glass, interfering with night vision. Therefore, there is an urgent need for a camera mounting bracket and system that solves the problems of non-adjustable angle and glass reflection associated with window-mounted cameras. Summary of the Invention

[0003] In view of the shortcomings or deficiencies of the prior art, the technical problem to be solved by this application is to provide a multi-dimensional adjustable window-mounted camera mounting bracket and system.

[0004] To solve the above-mentioned technical problems, this application provides the following technical solution: This application proposes a multi-dimensional adjustable window-mounted camera mounting bracket, including a base attached to the inner side of a transparent medium with a light-transmitting hole at its center; a flexible corrugated tube, one end of which is connected to the base and the other end of which is connected to the camera interface; the flexible corrugated tube is composed of multiple continuously arranged elastic pleats, which can be stretched, compressed, and deflected in three-dimensional space under external force; wherein, the other end of the flexible corrugated tube is also provided with a magnetic interface, the magnetic structure having a built-in magnetic attraction element, the magnetic attraction element being used to quickly connect with the camera body and form a sealed cavity.

[0005] The above solution, through the setting of flexible corrugated tubes, enables the camera to stretch, compress, and deflect in three-dimensional space, thereby achieving flexible adjustment of the shooting angle and solving the problem of fixed angle of traditional brackets; at the same time, the sealed cavity formed by the corrugated tubes, base, and camera effectively blocks indoor ambient light and avoids interference of glass reflection on night vision effect.

[0006] More preferably, the inner diameter of the flexible corrugated tube has a gradually expanding structure from the base end to the magnetic interface end, in order to adapt to the market requirements of wide-angle lenses for cameras.

[0007] This preferred solution increases the light-passing space in front of the lens by setting the inner diameter of the bellows to a gradually expanding shape, preventing the edge of the bellows from entering the image and causing obstruction when bent at a large angle, thus ensuring the field of view of the wide-angle lens.

[0008] More preferably, the inner wall of the flexible corrugated tube is further provided with a black light-absorbing texture for absorbing ambient light.

[0009] This preferred solution absorbs stray light through black light-absorbing texture, further reducing secondary reflections of light inside the bellows and improving image clarity.

[0010] More preferably, the inner wall of the flexible corrugated pipe is further provided with a matte coating for absorbing ambient light.

[0011] This preferred solution reduces the reflectivity of the inner wall through an anti-reflective coating, which also helps to suppress stray light and optimize image quality.

[0012] More preferably, the flexible corrugated pipe contains a damping additive in its material.

[0013] This preferred design allows the bellows to maintain its shape well after being bent under stress, overcoming the camera's gravity to maintain the current angle without the need for an additional locking mechanism, thus simplifying the operation process.

[0014] More preferably, the flexible corrugated pipe is a one-piece molded structure.

[0015] This preferred design enhances the overall structural strength and sealing of the support structure, while reducing assembly costs.

[0016] More preferably, it also includes a housing that covers the outside of the camera, the edge of the housing being connected to the flexible corrugated tube.

[0017] This preferred solution protects the camera with a housing and achieves a secure connection with the bellows.

[0018] This application also provides a multi-dimensional adjustable window-mounted camera installation system, comprising: a multi-dimensional adjustable window-mounted camera mounting bracket based on any one of the above claims and a camera, wherein the camera body is disposed inside the base.

[0019] The above solution, through the cooperation of brackets and cameras, constructs a complete window-mounted monitoring system, which has the advantages of both flexible angle adjustment and high image clarity.

[0020] More preferably, the camera lens is positioned facing the transparent medium, and the lens is positioned opposite to the light-transmitting hole.

[0021] This preferred design ensures that the camera lens can clearly capture external images through the light-transmitting holes in the base.

[0022] More preferably, the camera body is further provided with a magnetic suction part for connecting with the flexible corrugated tube, and the magnetic suction part is magnetically connected to the magnetic interface.

[0023] This preferred solution enables quick assembly and disassembly of the camera and bracket via magnetic connection, facilitating equipment maintenance and adjustment.

[0024] Compared with the prior art, this application has the following technical effects: The multi-dimensional adjustable window-mounted camera mounting bracket and system provided in this application have the following advantages: (1) Flexible and adjustable shooting angle: The flexible corrugated tube composed of multiple continuous elastic pleats allows the camera to be stretched, compressed and deflected in three-dimensional space. Users can adjust the angle at will according to actual monitoring needs (such as overhead view and side view), which solves the problem of limited viewing angle of traditional window brackets.

[0025] (2) Excellent anti-reflective performance: One end of the corrugated pipe is connected to the base, and the other end is connected to the camera through a magnetic interface to form a closed sealed cavity. This cavity effectively blocks indoor ambient light sources, avoids light reflection interference on the glass surface, and significantly improves the quality of night vision imaging.

[0026] (3) Stable and reliable structure: The corrugated pipe material contains damping additives, which have high damping and shaping function. After bending, it can overcome the gravity of the camera and maintain its shape without rebounding, without the need for frequent adjustments. At the same time, the gradually expanding inner diameter design and the light-absorbing treatment of the inner wall ensure the field of view of the wide-angle lens and suppress internal stray light. Attached Figure Description

[0027] Other features, objects, and advantages of this application will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings: Figure 1 : A schematic diagram of the overall structure of the multi-dimensional adjustable window-mounted camera mounting bracket according to an embodiment of this application in its initial state. Figure 1 ; Figure 2 A schematic diagram of the overall structure of a multi-dimensional adjustable window-mounted camera mounting bracket according to an embodiment of this application when rotated downwards by 30°. Figure 2 .

[0028] Figure label: 10-Outer shell; 11-Flexible corrugated pipe; 20-Camera body; 21-Lens; 30-Transparent medium. Detailed Implementation

[0029] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0030] like Figure 1 and Figure 2 As shown, this embodiment provides a multi-dimensional adjustable window-mounted camera 20 mounting bracket. The bracket mainly includes three core components: a base (not shown in the figure), a flexible corrugated tube 11, and a magnetic interface (not shown in the figure). Together, these three components form a mounting platform that can flexibly adjust the angle and effectively prevent reflections.

[0031] The base is attached to the inner side of the transparent medium 30 (such as glass). Specifically, the transparent medium 30 typically refers to window glass in a building, but can also be a light-transmitting material such as acrylic sheet or transparent plastic sheet. The base can be attached to the interior surface of the glass using double-sided tape, suction cups, or adhesives. A light-transmitting hole is provided at the center of the base, extending through the thickness of the base, allowing the lens 21 of the camera 20 to pass through and capture external images. The base serves as the fixed foundation for the entire bracket, providing a stable support point for subsequent components.

[0032] One end of the flexible corrugated tube 11 is connected to the base, and the other end is connected to the interface of the camera 20. The flexible corrugated tube 11 is composed of multiple continuously arranged elastic pleats, which can be stretched, compressed, and deflected in three-dimensional space under external force. Specifically, this corrugated tube structure is similar to a bendable straw or a snakeskin tube, and its tube wall is composed of a series of annular pleats, which give the tube body extremely high flexibility. When the user needs to adjust the monitoring angle of the camera 20, he only needs to apply tension, pressure, or torque to the flexible corrugated tube 11, and the tube body will deform accordingly. For example, if the user needs to look down from the second-floor window to monitor the entrance on the first floor, he can bend the flexible corrugated tube 11 downward to make it into an "L" shape or a "C" shape, thereby causing the lens 21 of the camera 20 to face diagonally downward; if he needs to observe the corridor from the side, he can bend the flexible corrugated tube 11 to the left or right. When the external force is removed, the flexible corrugated pipe 11 can maintain its current deformation state, thereby locking the shooting angle of the camera 20. This multi-dimensional adjustment capability solves the problems of limited viewing angle and inflexible adjustment of traditional window-mounted brackets.

[0033] The flexible corrugated tube 11 also has a magnetic interface at its other end. The magnetic structure incorporates a magnetic attraction element, which is used to quickly connect with the camera body 20 and form a sealed cavity. Specifically, the magnetic interface can be a ring-shaped structure with a magnet or magnetic material embedded inside. The camera body 20 has a corresponding magnetic attraction part (such as an iron sheet or magnet). When the camera 20 approaches the magnetic interface, the two can quickly attract and fix each other under magnetic force, achieving a quick "stick and use" experience. More importantly, when the camera 20 is connected to the end of the flexible corrugated tube 11 via the magnetic interface, the lens 21 end face of the camera 20, the inner wall of the flexible corrugated tube 11, the base, and the glass together form a closed, sealed cavity. This sealed cavity effectively isolates the lens 21 of the camera 20 from ambient light sources (such as lamps or reflective objects). During nighttime monitoring, indoor lights cannot illuminate the inner surface of the glass, thus completely eliminating the interference of glass reflection on the imaging of the camera 20 and ensuring the clarity of the night vision image.

[0034] Through the above structure, the bracket of this embodiment not only enables the camera 20 to be flexibly adjusted at any angle in three-dimensional space, but also solves the problem of glass reflection that plagues window-mounted monitoring through the sealed cavity formed by magnetic connection, significantly improving the applicability and imaging quality of the monitoring system.

[0035] Furthermore, based on Embodiment 1, this embodiment further optimizes the structure of the flexible corrugated tube 11. Specifically, the inner diameter of the flexible corrugated tube 11 gradually expands from the base end to the magnetic interface end to adapt to the market requirements of the wide-angle lens 21 of the camera 20.

[0036] The aforementioned gradually expanding structure refers to the fact that the diameter of the internal through-hole of the flexible bellows 11 is not constant, but gradually increases in the direction away from the base. Specifically, the inner diameter is smaller at the end closer to the base to match the size of the light-transmitting hole on the base, ensuring the sealing and structural compactness of the connection; while the inner diameter is larger at the end closer to the magnetic interface, forming a flared, trumpet-shaped or frustum-shaped space. This design is not an arbitrary choice of shape, but a targeted improvement based on the principle of optical imaging.

[0037] While conventional straight-tube corrugated pipes can be bent and adjusted in existing technologies, they have significant drawbacks when used with a wide-angle lens 21. The wide-angle lens 21 typically has a large field of view, requiring the imaging light to enter the lens 21 from a large spatial range. If the inner diameter of the flexible corrugated pipe 11 is constant and small, when the user bends the flexible corrugated pipe 11 significantly to obtain a specific monitoring angle (such as a top-down or side view), the pipe wall of the flexible corrugated pipe 11 can easily protrude into the field of view of the lens 21. This is analogous to looking through a bent straw, where the pipe wall obstructs part of the view. This obstruction manifests as dark shadows or vignetting on the screen, severely affecting the integrity and clarity of the monitoring image.

[0038] This embodiment effectively solves the aforementioned problem by setting the inner diameter of the flexible corrugated tube 11 to a gradually expanding shape. When the flexible corrugated tube 11 is bent at a large angle, due to the larger inner diameter near the end of the lens 21 (i.e., the magnetic interface end), a larger radial space is left between its tube wall and the lens 21. This flared structure provides an ample transmission channel for the wide-angle light of the wide-angle lens 21, avoiding the tube wall from blocking the light. Even when the corrugated tube is bent, the lens 21 can still capture external images without blind spots through the flared end, thereby ensuring the integrity of the imaging range of the wide-angle lens 21 and eliminating the black border phenomenon in the image.

[0039] It should be understood that the specific expansion ratio of the aforementioned gradually expanding structure can be designed according to the specific parameters (such as focal length and field of view) of the lens 21 of the adapted camera 20. For example, for a fisheye lens 21 with a larger field of view, the expansion ratio can be set to be larger; while for a regular wide-angle lens 21, the expansion ratio can be appropriately reduced. This structural flexibility allows the bracket of this application to be adapted to various types of cameras 20, and has wide applicability.

[0040] Furthermore, this embodiment further optimizes the internal microstructure, material, and molding process of the flexible corrugated pipe 11, aiming to construct a high-performance support integrating "material-structure-function". For example... Figure 2As shown, the inner wall of the flexible corrugated pipe 11 is also provided with a black light-absorbing texture for absorbing ambient light. Specifically, this black light-absorbing texture can be a micro-nano structure directly processed on the surface of the inner wall of the flexible corrugated pipe 11, such as an array of tiny protrusions or pits formed on the inner surface of the folds through a molding process. These tiny texture structures can disrupt the specular reflection path of light, causing the incident ambient light to undergo multiple diffuse reflections and absorptions inside the pipe wall, thereby effectively suppressing stray light interference. It should be understood that the form of the light-absorbing texture is not limited to the aforementioned micro-nano structures; it can also be a frosted texture, a knurled texture, or other structural forms that can increase surface roughness, as long as it can achieve the purpose of absorbing light and reducing reflection.

[0041] As an alternative implementation, the inner wall of the flexible corrugated pipe 11 is also provided with a matte coating for absorbing ambient light. Specifically, this matte coating can be a black matte paint, a black oxide layer, or a carbon nanotube coating sprayed or dipped onto the inner wall of the corrugated pipe. Unlike the physical textures mentioned above, the matte coating mainly relies on the low reflectivity of the material itself to absorb light. For example, black matte paint can absorb most of the visible light spectrum, and its reflectivity is usually less than 5%. In practical applications, light-absorbing textures and matte coatings can be used alone or in combination. For example, a matte coating can be sprayed onto a surface with a light-absorbing texture to achieve a more extreme light absorption effect. This design is particularly important for nighttime surveillance, as it can completely eliminate secondary reflection spots that may be generated on the inner wall of the corrugated pipe, ensuring that the camera 20 can still obtain a clear image with high contrast in low-light environments.

[0042] Furthermore, the flexible corrugated tube 11 contains damping additives in its material. The addition of these damping additives endows the corrugated tube with excellent shape retention capabilities. Specifically, the damping additives can be high-damping materials such as nano-silica, mica powder, or rubber particles, which are uniformly dispersed in the base material of the corrugated tube (such as thermoplastic elastomer TPE or silicone). When the flexible corrugated tube 11 is bent by an external force, the base material deforms, and relative slippage and friction occur between the dispersed damping additive particles. This microscopic internal friction consumes a large amount of mechanical energy, thus generating a high-damping effect. It is this high-damping characteristic that allows the flexible corrugated tube 11 to overcome the gravitational torque of the camera 20 after being bent to the target angle, steadily maintaining its current shape without springback or creep. This solves the problem that traditional corrugated tubes require an additional locking mechanism to fix the angle, greatly simplifying the user's operation process and improving the user experience.

[0043] Furthermore, the flexible corrugated pipe 11 is a one-piece molded structure. Specifically, the flexible corrugated pipe 11 can be manufactured in one step through processes such as injection molding, extrusion molding, or blow molding, without the need for subsequent splicing or assembly processes. The one-piece molded structure eliminates the assembly gaps present in traditional multi-segment spliced ​​structures, which not only significantly improves the overall structural strength and fatigue resistance of the corrugated pipe, but more importantly, it ensures the continuity and integrity of the inner wall of the corrugated pipe, further enhancing the airtightness of the sealed cavity and preventing light leakage. This structural design makes the support more reliable and durable during long-term use, reducing the risk of performance degradation due to loose connections.

[0044] Furthermore, the product form of the bracket has been further expanded. Specifically, the bracket in this embodiment also includes the outer shell 10, which covers the outside of the camera 20. The edge of the outer shell 10 is connected to the flexible corrugated tube 11. Figure 1 and Figure 2 As shown.

[0045] like Figure 1 and Figure 2 As shown, the housing 10, as an independent structural component, primarily functions to provide comprehensive physical protection for the camera 20. In practical applications, the camera 20 typically contains precision optical lenses 21 and electronic components, which are easily exposed to indoor environments and susceptible to accidental impacts, dust intrusion, or moisture corrosion. The housing 10 can be designed as a hemispherical, cylindrical, or streamlined enclosure to completely enclose the camera 20, thereby providing dustproof, moisture-proof, and impact-resistant protection, significantly extending the device's lifespan.

[0046] Regarding the connection method between the outer shell 10 and the flexible corrugated tube 11, specifically, the edge of the outer shell 10 may be provided with an annular groove, and the end of the flexible corrugated tube 11 near the camera 20 (i.e., the magnetic interface end) is provided with a matching flange, which is fixed by a snap-fit ​​connection. This connection method is not only easy to assemble, but also ensures a tight and seamless connection, effectively preventing light from seeping in through the connection gaps. It should be understood that the connection method is not limited to snap-fit ​​connection; it can also be threaded connection, magnetic adsorption, or strong adhesive bonding, as long as a stable and sealed connection is formed between the outer shell 10 and the flexible corrugated tube 11.

[0047] Furthermore, the outer casing 10 also plays a crucial role in enhancing sealing. When the outer casing 10 is connected to the flexible bellows 11, the internal space of the outer casing 10 and the internal channel of the flexible bellows 11 together form a larger sealed cavity. The camera 20 is located inside this sealed cavity, and its lens 21 observes the outside through the light-transmitting holes of the flexible bellows 11 and the base. This fully enclosed structural design, compared to the simple flexible bellows 11 structure, further improves the system's light-shielding performance, ensuring that even under strong light, indoor light cannot enter the field of view of the lens 21 from any gaps, thus completely eliminating glass reflection.

[0048] From a product design perspective, the presence of the housing 10 also enhances the overall aesthetics and consistency of the appearance. The housing 10 can be made of colors and materials that match the interior design style (such as matte black, porcelain white, etc.), concealing the originally obtrusive camera 20 within an aesthetically pleasing enclosure, allowing it to better integrate into the usage environment. Simultaneously, as a visible external component, the housing 10's features are easily observed and evidenced in the event of a patent infringement dispute, facilitating patent protection.

[0049] This embodiment also provides a multi-dimensional adjustable window-mounted camera mounting system. The system includes the multi-dimensional adjustable window-mounted camera 20 mounting bracket described in any of the above embodiments, and the camera 20. The camera 20 body is disposed inside the base. The technical solution for the multi-dimensional adjustable window-mounted camera mounting bracket is described above and will not be repeated here.

[0050] Specifically, this embodiment constructs a complete monitoring terminal. The camera 20, as the imaging core, is housed within a space enclosed by the base, the flexible corrugated tube 11, and the optional outer shell 10. The phrase "located inside the base" should be broadly interpreted as the camera 20 being enclosed or supported by the support structure. For example, in an embodiment without the outer shell 10, the camera 20 can be directly embedded in the light-transmitting area of ​​the base, or suspended within the corrugated tube channel via a magnetic interface; while in an embodiment incorporating the outer shell 10 described in Embodiment 4, the camera 20 is completely enclosed within the cavity formed by the outer shell 10 and the base. This arrangement integrates the camera 20 with the support, resulting in a neat appearance and, more importantly, providing a structural foundation for subsequent anti-reflective functions.

[0051] In this system, the lens 21 of the camera 20 is positioned facing the transparent medium 30, and the lens 21 is positioned opposite to the light-transmitting hole.

[0052] like Figure 2 As shown, the lens 21 of the camera 20 faces the light-transmitting hole on the base. The light-transmitting hole, as the sole entry point for light, is typically designed with a diameter slightly larger than the field of view of the lens 21 to ensure unobstructed light from external objects enters the lens 21. During actual installation, the user can fine-tune the distance between the lens 21 and the light-transmitting hole by adjusting the length of the flexible corrugated tube 11. Preferably, the front end of the lens 21 can be close to the light-transmitting hole or even directly abut against the inner surface of the transparent medium 30 (such as glass). This physical contact or extremely close proximity minimizes light loss during transmission and further compresses the internal reflection space.

[0053] Furthermore, the camera body 20 is also provided with a magnetic suction part for connecting with the flexible corrugated tube 11, and the magnetic suction part is magnetically connected to the magnetic interface.

[0054] Specifically, the magnetic attachment can be a ferromagnetic metal sheet pre-embedded in the housing 10 of the camera 20, or a magnetic ring integrally injection-molded with the housing 10 of the camera 20. During installation, the user simply holds the camera 20 and aligns its magnetic attachment with the magnetic interface at the end of the flexible corrugated tube 11. Under the influence of magnetic attraction, the two will automatically attract and align, producing a crisp "click" sound to indicate that the installation is complete. This process requires no screwdrivers or other tools, and does not require alignment of threads, greatly simplifying the installation process and enabling quick, "blind" disassembly and assembly. When the camera 20 needs to be removed for charging or maintenance, only a slight pulling force is required to overcome the magnetic attraction, making the operation very convenient.

[0055] Through the aforementioned connections, the system constructs a tightly sealed darkroom environment in actual operation. When the camera 20 is fixed to the magnetic interface via the magnetic attachment, the front face of the camera 20, the inner wall of the flexible corrugated tube 11, the base, and the transparent medium 30 together form a closed, sealed cavity. This sealed cavity completely physically isolates the lens 21 of the camera 20 from ambient light sources (such as chandeliers, table lamps, or other light entering from outside the window). In nighttime monitoring mode, even if the room is brightly lit, light cannot reach the glass surface in front of the lens 21. This fundamentally cuts off the light path reflected by the glass mirror, completely eliminating the "white reflection on the glass" or "indoor reflection interference" phenomena commonly seen in traditional window-mounted monitoring, ensuring that the camera 20 can clearly capture low-light images outdoors through the glass, significantly improving night vision imaging quality.

[0056] To more intuitively verify the actual effect of the technical solution of this application, a specific indoor window-mounted monitoring scenario is used as an example for illustration. The application scenario is set as follows: the user needs to install the camera 20 on the top of the window in the living room on the first floor to monitor the doorway area outside.

[0057] During installation, the user first attaches the base to the top of the inside of the window glass using double-sided adhesive. At this point, the initial orientation of the camera 20 is horizontal and outward. To obtain a monitoring perspective overlooking the doorway, the user needs to adjust the shooting angle of the camera 20. Specifically, the user manually holds the flexible corrugated tube 11 near the magnetic interface and applies a bending force downward. Because the flexible corrugated tube 11 is composed of multiple continuously arranged elastic pleats, its body deforms in three-dimensional space, being smoothly stretched and deflected into an "L" shape or an arc-shaped bend. This process fully demonstrates the multi-dimensional adjustment capability of the bracket; the user can flexibly change the monitoring direction according to on-site needs without disassembling the bracket or replacing the wedge-shaped gasket, solving the problem of fixed viewing angles in traditional window-mounted brackets.

[0058] Once the user adjusts the camera 20 to the desired overhead angle, the external force is removed. At this point, the damping additive contained in the flexible corrugated pipe 11 comes into play. Specifically, the damping additive generates a high damping effect within the pipe material, allowing the corrugated pipe to generate sufficient internal friction after deformation to overcome the gravitational torque generated by the camera 20. Therefore, the flexible corrugated pipe 11 can be stably locked in its current bending shape, without rebounding or creeping due to the weight of the camera 20, thus ensuring the stability of the monitoring image.

[0059] In nighttime monitoring mode, indoor lighting is typically on. Without effective light-blocking measures, indoor light will reflect off window glass, causing specular reflections. This reflected light entering the lens 21 can result in ghosting or a white haze, severely impacting image quality. In this embodiment, the camera 20 body is tightly connected to a magnetic interface via a magnetic suction unit, and the flexible corrugated tube 11 connects the base and the camera 20. Together, these three components form a sealed cavity around the lens 21. This sealed cavity completely physically isolates the camera 20's lens 21 from the indoor ambient light. Even with bright indoor lighting, light cannot reach the glass surface in front of the lens 21, thus completely cutting off the light path of glass reflections. The camera 20 can only receive outdoor light through the light-transmitting hole, thus obtaining clear, interference-free night vision images.

[0060] As can be seen from the above description of the actual operation scenario, the installation system of this embodiment not only realizes flexible and multi-dimensional adjustment of the shooting angle, but also effectively solves the problem of glass reflection at night by constructing a sealed cavity, significantly improving the practicality and imaging reliability of the window monitoring system.

[0061] In the description of this application, unless otherwise expressly specified and limited, the terms "connected," "linked," and "fixed" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.

[0062] In this application, unless otherwise expressly specified and limited, "above" or "below" the second feature can include direct contact between the first and second features, or contact between the first and second features through another feature between them. Furthermore, "above," "over," and "on top" of the second feature includes the first feature being directly above or diagonally above the second feature, or simply indicates that the first feature is at a higher horizontal level than the second feature. "Below," "below," and "under" the second feature includes the first feature being directly below or diagonally below the second feature, or simply indicates that the first feature is at a lower horizontal level than the second feature.

[0063] In the description of this embodiment, the terms "upper," "lower," "left," "right," etc., refer to the orientation or positional relationship shown in the accompanying drawings. They are used only for ease of description and simplification of operation, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this application. In addition, the terms "first" and "second" are used only for distinction in description and have no special meaning.

[0064] The above embodiments are only used to illustrate the technical solutions of this application and are not intended to limit it. The preferred embodiments have been described in detail. Those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of this application without departing from the spirit and scope of the technical solutions of this application, and all such modifications and substitutions should be covered within the scope of the claims of this application.

Claims

1. A multi-dimensional adjustable window-mounted camera mounting bracket, characterized in that, include: A base, which is attached to the inside of a transparent medium and has a light-transmitting hole in its center; A flexible corrugated pipe, one end of which is connected to the base and the other end of which is connected to the camera interface. The flexible corrugated pipe is composed of multiple continuously arranged elastic folds, which can be stretched, compressed and deflected in three-dimensional space under the action of external force; The other end of the flexible corrugated tube is also provided with a magnetic interface. The magnetic structure has a built-in magnetic attraction element, which is used to quickly connect with the camera body and form a sealed cavity.

2. The multi-dimensional adjustable window-mounted camera mounting bracket according to claim 1, characterized in that, The inner diameter of the flexible corrugated tube gradually expands from the base end to the magnetic interface end to adapt to the market requirements of wide-angle camera lenses.

3. The multi-dimensional adjustable window-mounted camera mounting bracket according to claim 1, characterized in that, The inner wall of the flexible corrugated pipe is also provided with a black light-absorbing texture for absorbing ambient light.

4. The multi-dimensional adjustable window-mounted camera mounting bracket according to claim 1, characterized in that, The inner wall of the flexible corrugated pipe is also provided with a matte coating for absorbing ambient light.

5. The multi-dimensional adjustable window-mounted camera mounting bracket according to any one of claims 1 to 4, characterized in that, The flexible corrugated pipe contains damping additives in its material.

6. The multi-dimensional adjustable window-mounted camera mounting bracket according to any one of claims 1 to 4, characterized in that, The flexible corrugated pipe is a one-piece molded structure.

7. The multi-dimensional adjustable window-mounted camera mounting bracket according to any one of claims 1 to 4, characterized in that, It also includes a housing that covers the exterior of the camera, the edges of which are connected to the flexible bellows.

8. A multi-dimensional adjustable window-mounted camera installation system, characterized in that, include: Based on the multi-dimensional adjustable window-mounted camera mounting bracket and camera as described in any one of claims 1 to 7, the camera body is disposed inside the base.

9. The multi-dimensional adjustable window-mounted camera installation system according to claim 8, characterized in that, The camera lens is positioned facing the transparent medium, and the lens is positioned opposite the light-transmitting hole.

10. The multi-dimensional adjustable window-mounted camera installation system according to claim 8, characterized in that, The camera body is also provided with a magnetic suction part for connecting with the flexible corrugated tube, and the magnetic suction part is magnetically connected to the magnetic interface.