A remote control monitoring device

By integrating multiple sensors and adjustment components, the remote fire control and monitoring device solves the problem of insufficient environmental monitoring capabilities of existing devices, realizes comprehensive and flexible environmental monitoring, and improves the fire emergency response capability.

CN224404241UActive Publication Date: 2026-06-26SHENZHEN LIKE INTELLIGENT BUILDING TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN LIKE INTELLIGENT BUILDING TECHNOLOGY CO LTD
Filing Date
2025-07-25
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing remote fire control and monitoring devices do not perform well in autonomous environmental monitoring and cannot independently and accurately monitor the actual situation in the surrounding area, making it impossible for managers to intuitively and truly grasp the dynamics on site.

Method used

A remote fire control and monitoring device was designed, which integrates a smoke sensor, a temperature sensor, a combustible gas detector, and a data processing and communication module. Combined with a drive motor and adjustment components, it realizes the horizontal rotation and pitch adjustment of the camera, and is equipped with a laser to provide positioning reference, forming a multi-dimensional environmental perception.

Benefits of technology

It enables comprehensive and flexible monitoring of the surrounding environment, allowing for rapid and accurate assessment of fire situations, improving fire emergency response capabilities, avoiding monitoring blind spots, and enhancing the comprehensiveness and reliability of autonomous environmental monitoring.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224404241U_ABST
    Figure CN224404241U_ABST
Patent Text Reader

Abstract

The utility model provides a kind of monitoring device of remote control, belong to mechanical technical field.The monitoring device of remote control, including shell and shell inboard wall installation has monitoring mechanism, it is characterized by: shell inner bottom is embedded with bearing, and edge bolt is fixed with driving motor, driving motor output end extends to bearing inner ring, shell bottom end is equipped with adjusting component, adjusting component top end outer wall is fixedly connected with bearing inner ring and is inserted with driving motor output end, adjusting component bottom end is equipped with camera, laser is integrally made into the bottom of camera, laser output end and camera camera end are arranged in the same direction, wherein, by the control of monitoring mechanism in shell, and the organic linkage of bearing, driving motor, adjusting component, camera and laser, the device successfully solves the problem that existing remote control monitoring device is difficult to be independent, accurately grasps surrounding actual situation, ensures the clear insight and effective perception to environmental condition.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application relates to the field of machinery, and more specifically, to a remote fire control monitoring device. Background Technology

[0002] With the continuous expansion of modern building scale and increasing complexity of functions, as well as the ever-increasing demands for fire safety management, traditional fire protection facilities are no longer sufficient to meet the requirements of real-time, efficient, and intelligent monitoring and control. Against this backdrop, remote fire control and monitoring devices have emerged. Combining sensor technology, communication technology, and computer technology, they enable remote monitoring and management of fire protection facilities and the environment. By installing various sensors within the building, the collected fire data (such as smoke concentration, temperature, and flame patterns) is transmitted to the monitoring center via wired or wireless networks, allowing management personnel to monitor the on-site fire situation in real time.

[0003] Currently, remote fire control and monitoring devices are widely used in many locations, including commercial buildings, industrial plants, and residential communities. These devices typically consist of sensor modules, data acquisition modules, and communication modules. The sensor modules collect fire parameters from the environment, the data acquisition modules process and convert the data collected by the sensors, and the communication modules transmit the processed data to the monitoring center. The monitoring center software then analyzes and displays the received data and provides alarm and management functions. However, existing remote fire control and monitoring devices perform poorly in autonomous environmental monitoring, failing to independently and accurately monitor the surrounding conditions. This prevents managers from using the device to intuitively and accurately grasp the dynamics of the scene. Utility Model Content

[0004] To overcome the above deficiencies, this application provides a remote fire control monitoring device to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, the technical solution adopted by this utility model to solve its technical problem is as follows:

[0006] A remote fire control monitoring device includes a housing and a monitoring mechanism installed on the inner wall of the housing. The device is characterized in that: a bearing is embedded in the bottom of the housing, and a drive motor is fixed to its edge with bolts; the output end of the drive motor extends to the inner ring of the bearing; an adjustment component is installed at the bottom of the housing; the outer wall of the top of the adjustment component penetrates the bottom of the housing and is fixedly connected to the inner ring of the bearing, and is inserted into the output end of the drive motor; a camera is provided at the bottom of the adjustment component; a laser is integrally formed at the bottom of the camera, and the laser output end of the laser and the camera's image input end are in the same direction.

[0007] Furthermore, the outer wall of the bearing is embedded in the stepped groove opened at the bottom of the housing, and the inner ring is fixedly welded to the outer wall of the top of the adjusting component.

[0008] Furthermore, the fixed end of the drive motor is fixedly connected to the threaded hole bolt on the bottom of the housing, and the output end extends to the inner ring of the bearing and is inserted into the top of the adjustment component.

[0009] Furthermore, the adjustment component includes a mounting plate, a top column, a plug slot, a connecting rod, two hinge blocks, a telescopic cylinder, and two hinge joints. The surface of the mounting plate is integrally formed with the bottom end of the top column and fits against the bottom of the outer shell. The top end of the top column penetrates the bottom of the outer shell, and its outer wall is welded to the inner ring of the bearing. The plug slot is formed at the top end of the top column and the output end of the drive motor is inserted inside. The two ends of the connecting rod are respectively hinged to the opposite ends of the two hinge blocks. The disjoint ends of the two hinge blocks are integrally formed with the bottom of the mounting plate and the surface of the camera, respectively. The telescopic cylinder is inclined and its two ends are respectively hinged to the opposite ends of the two hinge joints. The disjoint ends of the two hinge joints are integrally formed with the tail end of the bottom of the mounting plate and the tail end of the surface of the camera, respectively.

[0010] Furthermore, a sunshade is integrally formed on the top of the camera lens and is connected to the monitoring agency for signal transmission.

[0011] Furthermore, the top of the outer casing is provided with a cover plate, and the cover plate and the four corners of the outer casing surface are provided with mounting holes and are chamfered.

[0012] Furthermore, the four corners of the outer casing are chamfered, and each of the four chamfered arc surfaces has a number of heat dissipation holes.

[0013] Furthermore, the monitoring mechanism includes a smoke sensor, a temperature sensor, a combustible gas detector, an alarm, and a data processing and communication module. The smoke sensor, the temperature sensor, the combustible gas detector, and the alarm are respectively installed on the four sides of the outer wall of the housing. The data processing and communication module is installed on the top inside the cover plate and is electrically connected to the drive motor, the smoke sensor, the temperature sensor, the combustible gas detector, and the alarm.

[0014] This utility model has the following beneficial effects:

[0015] 1. This utility model utilizes a bearing embedded in the bottom of the outer casing and a drive motor to enable the adjustment component to rotate horizontally. The output end of the drive motor extends to the inner ring of the bearing and connects to the top of the adjustment component, allowing the drive motor to drive the adjustment component to perform circular motion on the horizontal plane. This, in turn, causes the bottom camera to rotate horizontally, expanding the camera's monitoring range and enabling a comprehensive scan of the surrounding environment, avoiding blind spots. Furthermore, the telescopic cylinder in the adjustment component is tilted, with its two ends hinged to hinge joints at the bottom of the mounting plate and the rear end of the camera surface, respectively. The connecting rod's two ends are connected to the bottom of the mounting plate and the camera surface via hinge blocks. The telescopic movement of the cylinder changes the camera's pitch angle, allowing the camera to flexibly adjust its viewing angle according to actual monitoring needs. Whether observing details at close range or monitoring large areas from a distance, this can be easily achieved, further improving the flexibility and effectiveness of monitoring. Additionally, the camera is connected to the monitoring mechanism, enabling correlation analysis between the monitoring footage and sensor data. When a sensor detects an anomaly, the camera can automatically turn to that area for focused monitoring, providing managers with more intuitive and detailed information. This helps to quickly and accurately assess the fire situation, formulate reasonable rescue plans, and improve fire emergency response capabilities.

[0016] 2. The laser unit of this utility model is integrally formed at the bottom of the camera, with its laser output end and the camera's image input end facing the same direction. The laser emitted by the laser unit can provide a positioning reference for the camera, helping operators to more accurately determine the camera's monitoring direction and target location. Especially in complex environments, it can quickly locate areas that need to be monitored, improving monitoring efficiency.

[0017] 3. This utility model's monitoring mechanism integrates multiple sensors, including smoke sensors, temperature sensors, and combustible gas detectors, enabling real-time and accurate monitoring of key environmental parameters. This data, along with visual information from cameras and detection data from lasers, is aggregated into a data processing and communication module, forming a comprehensive situational awareness of the monitoring point and its surrounding environment. This effectively solves the problems of limited environmental monitoring capabilities and information silos inherent in existing devices. Attached Figure Description

[0018] To more clearly illustrate the technical solutions of the embodiments of this application, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this application and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained from these drawings without creative effort.

[0019] Figure 1 This is a schematic diagram of the remote fire control monitoring device provided in the embodiments of this application;

[0020] Figure 2 A schematic diagram of the internal structure of the outer casing provided for an embodiment of this application;

[0021] Figure 3 A bottom view of the cover plate structure provided for an embodiment of this application;

[0022] Figure 4 A schematic diagram of the connection structure between the adjustment component and the camera provided in the embodiments of this application;

[0023] Figure 5 A schematic diagram of the connection structure between the adjustment component and the bearing provided in the embodiments of this application.

[0024] In the diagram: 1-Outer shell; 2-Monitoring mechanism; 21-Smoke sensor; 22-Temperature sensor; 23-Combustible gas detector; 24-Alarm; 25-Data processing and communication module; 3-Bearing; 4-Drive motor; 5-Adjusting component; 51-Mounting plate; 52-Top column; 53-Plug-in slot; 54-Connecting rod; 55-Hinge block; 56-Telescopic cylinder; 57-Hinge joint; 6-Camera; 61-Sunshade; 7-Laser; 8-Cover plate; 9-Heat dissipation hole. Detailed Implementation

[0025] The technical solutions in 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.

[0026] Example:

[0027] Please see Figure 1 , Figure 2 , Figure 3 A remote fire control monitoring device includes a housing 1 and a monitoring mechanism 2 installed on the inner side wall of the housing 1; the monitoring mechanism 2 includes a smoke sensor 21, a temperature sensor 22, a combustible gas detector 23, an alarm 24 and a data processing and communication module 25; the top of the housing 1 is provided with a cover plate 8; the four corners of the housing 1 are chamfered, and the four chamfered arc surfaces are respectively provided with a number of heat dissipation holes 9.

[0028] The outer casing 1 is made of high-strength, corrosion-resistant metal material to ensure stable operation in various harsh environments. The four corners of the outer casing 1 are chamfered, which not only improves its aesthetics but also prevents potential injury from sharp edges. The surface of the outer casing 1 is treated with rust prevention, further enhancing its durability.

[0029] The monitoring unit 2 provides comprehensive, real-time monitoring of the surrounding environment. A smoke sensor 21, preferably an optical smoke sensor, is installed on the first side wall of the housing 1 to effectively detect smoke particles generated in early fires. A temperature sensor 22, such as a high-precision thermistor or digital temperature sensor, is installed on the second side wall to monitor changes in ambient temperature in real time. A combustible gas detector 23, such as a catalytic combustion or semiconductor detector, is installed on the third side wall to detect the concentration of combustible gases such as methane, liquefied petroleum gas, and natural gas in the environment. An audible and visual alarm 24 is installed on the fourth side wall, capable of emitting a high-decibel sound and flashing a bright light to provide on-site alarm when danger is detected. The core control and data processing unit of the monitoring unit 2 is the data processing and communication module 25. This module 25 is installed in the top space within the cover plate 8 on the top of the housing 1. The module 25 integrates a microprocessor such as a single-chip microcomputer or embedded processor, a data storage unit, and a wireless communication module, such as a module supporting Wi-Fi or 4G / 5G cellular networks. The data processing and communication module 25 establishes electrical connections via wires embedded in the wall of the housing 1 to the drive motor 4 (used to control the rotation of the camera and laser), the smoke sensor 21, the temperature sensor 22, the combustible gas detector 23, and the audible and visual alarm 24. During operation, the smoke sensor 21, temperature sensor 22, and combustible gas detector 23 monitor their respective environmental parameters in real time and transmit the detected analog or digital signals to the data processing and communication module 25 via wires. The microprocessor of the data processing and communication module 25 processes and analyzes the received data. For example, when the smoke concentration exceeds a threshold, the temperature rises sharply, or the combustible gas concentration exceeds the standard, the data processing and communication module 25 immediately makes a judgment. On one hand, it triggers the audible and visual alarm 24 connected to the data processing and communication module 25 to activate, issuing an alarm at the device's location. On the other hand, the data processing and communication module 25 transmits alarm information, including sensor type, value, time, and location, to a remote monitoring center or the mobile terminal of management personnel in real time via its built-in wireless communication module. Simultaneously, the data processing and communication module 25 can also receive remote commands to control the drive motor 4 to rotate the camera 6 and laser 7, thereby adjusting the monitoring angle or performing detailed scanning of specific areas. This structure, which distributes multiple sensors around the housing 1 and manages them centrally via the data processing and communication module, overcomes the limitations of single monitoring methods, enabling multi-dimensional and comprehensive perception of the environment surrounding the monitoring point. This significantly improves the comprehensiveness and reliability of autonomous environmental monitoring, effectively addressing the shortcomings of similar products in the current market for environmental monitoring.

[0030] The cover plate 8 is a key component installed on the top of the housing 1 of the remote fire control and monitoring device. Its main function is to protect the core electronic components inside, especially the data processing and communication module 25. The cover plate 8 is preferably made of the same material as the housing 1. Mounting holes are correspondingly provided at the four corners of both the housing 1 and the cover plate 8. These mounting holes are typically designed as round holes of the same diameter, used to pass screws or other fasteners to securely connect the housing 1 and the cover plate 8 together, forming a sealed or semi-sealed cavity. This facilitates installation and operation.

[0031] The design of the heat dissipation holes 9 ensures that the electronic components inside the housing 1 can maintain a suitable operating temperature during long-term operation. The heat dissipation holes 9 are evenly distributed on the chamfered arc surface. This distribution can effectively cover the heat concentration areas at the four corners of the housing 1, while avoiding excessive impact on the overall appearance.

[0032] Please see Figure 1 , Figure 2 , Figure 4 , Figure 5 A remote fire control monitoring device includes a housing 1 with a bearing 3 embedded in the bottom and a drive motor 4 fixed to the edge by bolts. The output end of the drive motor 4 extends to the inner ring of the bearing 3. An adjustment component 5 is installed at the bottom of the housing 1. The outer wall of the top of the adjustment component 5 penetrates the bottom of the housing 1 and is fixedly connected to the inner ring of the bearing 3, and is plugged into the output end of the drive motor 4. A camera 6 is provided at the bottom of the adjustment component 5. A laser 7 is integrally formed at the bottom of the camera 6. The laser output end of the laser 7 and the camera end of the camera 6 are in the same direction. The adjustment component 5 includes a mounting plate 51, a top column 52, a plug groove 53, a connecting rod 54, two hinge blocks 55, a telescopic cylinder 56, and two hinge joints 57. A sunshade 61 is integrally formed on the top of the camera end of the camera 6.

[0033] The bearing 3 is a key component that supports the rotation of the adjusting component 5 and ensures the smooth, low-friction rotation of the camera 6 and laser 7. The bearing 3 is firmly fixed inside a stepped groove at the bottom of the housing 1, and its inner ring is rigidly connected to the adjusting component 5. When the drive motor 4 operates, power is transmitted to the adjusting component 5 through its output end. Because the adjusting component 5 is welded to the inner ring of the bearing 3, the bearing 3 can drive the adjusting component 5, camera 6, and laser 7 to achieve smooth, low-friction rotation. The stepped groove design enhances the stability of the connection, while welding provides extremely high connection strength, ensuring the long-term reliable operation of the rotating components.

[0034] The drive motor 4 is the core power source for rotating the adjustment component 5 and the camera 6 and laser 7 mounted on it. The drive motor 4 is bolted to the bottom of the housing 1, and its power output shaft is reliably connected to the insertion slot 53 of the adjustment component 5. When the drive motor 4 is powered on, the generated torque is transmitted to the top column 52 of the adjustment component 5 through the output shaft, thereby driving the entire rotating mechanism, including the camera 6 and laser 7, to rotate around the bearing 3 as a base point. The bolt fixing ensures the stable installation of the drive motor 4, while the precise insertion ensures effective power transmission and rotational synchronization, enabling flexible control of the monitoring field of view.

[0035] The adjusting component 5 is a key structure connecting the bearing 3 and the camera 6. It not only supports the camera 6 and laser 7, but also, through its internal hinge and telescopic mechanism, enables the camera 6 to adjust its vertical tilt, thereby expanding the monitoring field of view. The mounting plate 51 serves as the basic mounting platform for the adjusting component 5, its surface tightly fitting the bottom of the outer casing 1 to ensure the stability of the overall structure. The bottom of the mounting plate 51 is the mounting base for other connecting components. The bottom end of the top post 52 is integrally formed with the surface of the mounting plate 51, and its bottom end fits together with the mounting plate 51 at the bottom of the outer casing 1. The top end of the top post 52 penetrates the bottom of the outer casing 1, and its outer wall is firmly connected to the inner ring of the bearing 3 by welding. This allows the entire adjusting component 5 to rotate around the vertical axis along with the bearing 3. The top end of the top post 52 has a slot 53 for accommodating and fixing the output end of the drive motor 4, transmitting the motor's rotational power to the adjusting component 5. The two ends of the connecting rod 54 are respectively hinged to two hinge blocks 55. One hinge block 55 is integrally formed with the bottom of the mounting plate 51, and the other hinge block 55 is integrally formed with the surface of the camera 6. This forms a structure to fix the camera 6, whose main function is to maintain the stability of its horizontal posture and reduce swaying when the camera 6 is adjusted in pitch. The telescopic cylinder 56 is installed at an angle. Its two ends are hinged to two hinge joints 57 respectively. One hinge joint 57 is integrally formed with the bottom end of the mounting plate 51, and the other hinge joint 57 is integrally formed with the end of the surface of the camera 6. The extension and retraction of the telescopic cylinder 56 directly drives the camera 6 to adjust its pitch angle around the hinge point formed by the connecting rod 54. When the telescopic cylinder 56 extends, the camera 6 tilts upward; when the telescopic cylinder 56 retracts, the camera 6 tilts downward. By controlling the extension and retraction length of the telescopic cylinder 56, precise pitch adjustment of the camera 6 within a preset angle range can be achieved.

[0036] Through the aforementioned design, the adjustment component 5 achieves dual adjustment functions: relying on its fixed connection with the bearing 3 and the power input from the drive motor 4, the entire adjustment component 5 can drive the camera 6 to rotate horizontally within a 360-degree or specified angle range, achieving a wide-range horizontal scan. Furthermore, relying on the telescopic movement of the telescopic cylinder 56, combined with the stable structure formed by the connecting rod 54 and the hinge block 55, the camera 6 can be tilted vertically, thereby monitoring objects or areas at different heights and avoiding blind spots caused by installation height limitations. This structural design allows the remote fire control monitoring device to not only rotate horizontally like a "head" but also swing vertically like a "neck," greatly enhancing its environmental perception and monitoring coverage, making it particularly suitable for scenarios requiring comprehensive, blind-spot-free monitoring.

[0037] The camera 6 and laser 7 are integrated into the adjustment component 5 and share the same pitch and horizontal rotation movements. The camera 6 captures visual image information of the monitored area, while the laser 7 emits a laser beam to assist in ranging, target marking, or enhance visual recognition under specific conditions. Their close cooperation significantly improves the device's environmental awareness. The sunshade 61 on top of the camera 6 is a one-piece design, primarily designed to prevent direct sunlight, rain, or dust from entering the lens, ensuring image clarity and stability, especially outdoors or in harsh environments. The drive motor 4 rotates the adjustment component 5 horizontally, while the telescopic cylinder 56 may perform preset pitch adjustments, allowing the camera 6 and laser 7 to scan the preset monitoring area. The camera 6 captures images in real time and transmits the image data to the data processing and communication module 25.

[0038] The remote fire control monitoring device works as follows: When the smoke sensor 21, temperature sensor 22, and combustible gas detector 23 are triggered, the data processing module 25 immediately receives the relevant information and starts the drive motor 4 to drive the adjusting component 5 to start rotating horizontally. At the same time, the telescopic cylinder 56 controls the pitch angle of the camera 6 and the laser 7. The camera 6 captures images in real time, and the data processing module 25 analyzes the images transmitted back by the camera 6, combining them with the real-time data from the smoke sensor 21, temperature sensor 22, and combustible gas detector 23 to determine whether there are any abnormalities such as fire or gas leaks. When a potential target is detected or precise positioning is required, the data processing module 25 controls the laser 7 to emit a laser beam. Simultaneously, the alarm 24 is activated to sound an alarm, and the alarm information, including sensor type, value, time, and location, is sent in real time to the remote monitoring center or the mobile terminal of the management personnel.

[0039] It should be noted that the specific models and specifications of the smoke sensor 21, temperature sensor 22, combustible gas detector 23, alarm 24, data processing and communication module 25, drive motor 4, telescopic cylinder 56, camera 6, and laser 7 need to be selected and determined according to the actual specifications of the device. The specific selection and calculation method adopts the existing technology in this field, so it will not be described in detail.

[0040] The power supply and operating principles of the smoke sensor 21, temperature sensor 22, combustible gas detector 23, alarm 24, data processing and communication module 25, drive motor 26, telescopic cylinder 56, camera 6, and laser 7 are clear to those skilled in the art and will not be described in detail here.

[0041] It will be apparent to those skilled in the art that this application is not limited to the details of the exemplary embodiments described above, and that this application can be implemented in other specific forms without departing from the spirit or essential characteristics of this application. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this application is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within this application. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A remote fire control monitoring device, comprising a housing (1) and a monitoring mechanism (2) installed on the inner sidewall of the housing (1), characterized in that: The bottom of the housing (1) is embedded with a bearing (3), and a drive motor (4) is fixed to the edge with bolts. The output end of the drive motor (4) extends to the inner ring of the bearing (3). An adjustment component (5) is installed at the bottom of the housing (1). The outer wall of the top of the adjustment component (5) penetrates the bottom of the housing (1) and is fixedly connected to the inner ring of the bearing (3), and is inserted into the output end of the drive motor (4). A camera (6) is provided at the bottom of the adjustment component (5). A laser (7) is integrally formed at the bottom of the camera (6). The laser output end of the laser (7) and the camera end of the camera (6) are in the same direction.

2. The remote fire control monitoring device according to claim 1, characterized in that, The outer wall of the bearing (3) is embedded in the stepped groove opened at the bottom of the outer shell (1), and the inner ring is fixedly welded to the outer wall of the top of the adjusting component (5).

3. The remote fire control monitoring device according to claim 2, characterized in that, The fixed end of the drive motor (4) is fixedly connected to the threaded hole bolt at the bottom of the housing (1), and the output end extends to the inner ring of the bearing (3) and is inserted into the top of the adjustment component (5).

4. The remote fire control monitoring device according to claim 3, characterized in that, The adjusting component (5) includes a mounting plate (51), a top column (52), a insertion slot (53), a connecting rod (54), two hinge blocks (55), a telescopic cylinder (56), and two hinge joints (57). The surface of the mounting plate (51) is integrally formed with the bottom end of the top column (52) and fits against the bottom of the outer shell (1). The top end of the top column (52) penetrates the bottom of the outer shell (1), and its outer wall is welded to the inner ring of the bearing (3). The insertion slot (53) is opened at the top end of the top column (52) and is inserted into the top. The drive motor (4) has an output end. The two ends of the connecting rod (54) are respectively hinged to the opposite ends of the two hinge blocks (55). The two hinge blocks (55) are respectively integrally formed with the bottom of the mounting plate (51) and the surface of the camera (6). The telescopic cylinder (56) is inclined and its two ends are respectively hinged to the opposite ends of the two hinge joints (57). The two hinge joints (57) are respectively integrally formed with the bottom end of the mounting plate (51) and the surface end of the camera (6).

5. The remote fire control monitoring device according to claim 4, characterized in that, The camera (6) has a sunshade (61) integrally formed on the top of the camera end, and is connected to the monitoring agency (2) for signal transmission.

6. The remote fire control monitoring device according to claim 5, characterized in that, The top of the outer shell (1) is provided with a cover plate (8), and the cover plate (8) and the four corners of the outer shell (1) are provided with mounting holes and are chamfered.

7. The remote fire control monitoring device according to claim 6, characterized in that, The outer shell (1) has chamfered corners, and the four chamfered arc surfaces are provided with a number of heat dissipation holes (9).

8. The remote fire control monitoring device according to claim 7, characterized in that, The monitoring mechanism (2) includes a smoke sensor (21), a temperature sensor (22), a combustible gas detector (23), an alarm (24), and a data processing and communication module (25). The smoke sensor (21), the temperature sensor (22), the combustible gas detector (23), and the alarm (24) are respectively installed on the four sides of the outer wall of the outer shell (1). The data processing and communication module (25) is installed on the top inside the cover plate (8) and is electrically connected to the drive motor (4), the smoke sensor (21), the temperature sensor (22), the combustible gas detector (23), and the alarm (24).