A power plant operation monitoring assistance device and a scanning monitoring system

By using power plant operation monitoring auxiliary devices and scanning monitoring systems, the problems of large information volume and low camera adjustment efficiency in power plant monitoring systems have been solved, enabling real-time capture and timely processing of key information and improving the practicality of the monitoring system.

CN122160475APending Publication Date: 2026-06-05GUIZHOU WUJIANG HYDROPOWER DEV

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
GUIZHOU WUJIANG HYDROPOWER DEV
Filing Date
2024-03-28
Publication Date
2026-06-05

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Abstract

The application relates to the technical field of power plants, in particular to a power plant operation monitoring auxiliary device and a scanning monitoring system. The power plant operation monitoring auxiliary device comprises a monitoring assembly, a bottom support, a shell arranged at the top end of the bottom support, a monitoring element installed at the top end of the shell, a fixing element for connecting the monitoring element and the shell, and the monitoring element is arranged in the shell; an adjusting assembly comprises a driving element arranged in the shell, two cameras can be simultaneously moved through the rotation of the motor, the adjusting efficiency of the camera is improved, the driving element enters the working mode only when the fixing element is connected, the trouble of false touch is reduced, real-time scanning and accurate analysis are realized, the practicability of the monitoring system is greatly improved, the application of white list management reduces the false alarm rate, and it is ensured that key information can be timely processed by monitoring personnel.
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Description

Technical Field

[0001] This invention relates to the field of power plant technology, and in particular to a power plant operation monitoring auxiliary device and scanning monitoring system. Background Technology

[0002] With the rapid development of the power industry, the installed capacity of power plants continues to expand, and various auxiliary equipment is constantly increasing. This has led to an explosive growth in the amount of information carried by computer monitoring systems. Against this backdrop, operation and monitoring personnel face enormous work pressure and challenges. They need to pay close attention to every piece of information in the monitoring system at all times to ensure the safe operation of main and auxiliary equipment. However, due to the huge amount of information, monitoring personnel can easily miss key fault information due to fatigue or negligence, resulting in untimely fault handling or even safety accidents.

[0003] Meanwhile, ordinary monitoring devices cannot meet the monitoring needs of the power plant's curved screen. Using two monitoring devices requires adjusting the positions of the two cameras each time, and sometimes the adjustment is prone to misalignment, resulting in blind spots. Adjusting the two monitoring cameras separately greatly affects the installation efficiency. Summary of the Invention

[0004] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.

[0005] In view of the problem that adjusting one or two surveillance cameras separately greatly affects installation efficiency, this invention is proposed.

[0006] Therefore, one of the objectives of this invention is to provide an auxiliary device for monitoring the operation of a power plant.

[0007] To solve the above-mentioned technical problems, the present invention provides the following technical solution: including a monitoring component, comprising a base and a housing disposed at the top of the base, wherein a monitoring component is installed at the top of the housing, the monitoring component and the housing are connected by a fastener, and the monitoring component is located inside the housing;

[0008] The adjustment assembly includes a drive component disposed inside the housing and a limiting component disposed at the top of the drive component for fixing the motor, wherein a limiting plate is installed at the top of the limiting component through the housing.

[0009] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the monitoring component further includes a control key disposed on the side wall of the housing, an audible alarm disposed at the bottom of the control key for alarm purposes, and a light alarm disposed at the top of the control key.

[0010] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the monitoring component includes a camera disposed inside the housing, an annular plate disposed on the side wall of the camera, and a filter disposed on the side wall of the annular plate.

[0011] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the monitoring component further includes a hemisphere disposed on the side wall of the annular plate, the camera and the annular plate being located inside the hemisphere, and a rack being disposed at the end of the hemisphere.

[0012] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the monitoring component further includes a toothed disc disposed at the bottom end of the annular plate, a dust cover is installed on the outer wall of the housing, the dust cover is matched with the camera, and the filter corresponds to the camera.

[0013] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the fixing component includes a mounting plate disposed at the top of the housing, a top plate being mounted on the top of the mounting plate, a limiting groove being installed inside the mounting plate, a rotating block being installed inside the limiting groove, a threaded groove being provided inside the rotating block, and a fixing groove being provided at the top of the rotating block.

[0014] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the fixing component further includes an insert plate disposed at the bottom end of the housing, a rotating rod installed inside the insert plate, a fixing rod matching the fixing groove on the side wall of the rotating rod, an insert rod matching the slot installed at the top of the fixing rod, and a toggle plate disposed inside the slot.

[0015] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the driving component includes a driving gear disposed at the output end of the motor, the top end and side wall of the driving gear are provided with tooth blocks, the top end of the driving gear is equipped with a driven gear, the top end of the driving gear is equipped with a rotating rod, and the side wall of the rotating rod is sleeved with a limiting sleeve.

[0016] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the limiting member includes a first telescopic spring disposed on the side wall of the rotating rod, a threaded cylinder is disposed on the side wall of the rotating rod, a second telescopic spring is disposed on the inner wall of the threaded cylinder, and the thread on the rotating rod matches the thread on the inner wall of the threaded cylinder.

[0017] As a preferred embodiment of the power plant operation monitoring auxiliary device of the present invention, the limiting member further includes an inclined block disposed at the bottom end of the threaded cylinder, the inclined block being sleeved on the side wall of the hinge shaft, and the side wall of the threaded cylinder being provided with a downward pressure groove matching the inclined block, the surface of the downward pressure groove in contact with the inclined block being inclined.

[0018] The beneficial effects of the power plant operation monitoring auxiliary device described in this invention are as follows: This invention uses a monitoring component to monitor and capture data on the large screen in the power plant monitoring room. The monitoring component can drive two cameras to adjust their range through a drive component, reducing blind spots. At the same time, it does not require separate adjustments. The rotation of the motor can drive the two cameras to move simultaneously, improving the adjustment efficiency of the cameras. Furthermore, the drive component only enters the working mode when the device's fixing components are connected, reducing the trouble of accidental touches.

[0019] In actual use, there is a problem that monitoring personnel may easily miss key fault information due to fatigue or negligence, resulting in untimely fault handling.

[0020] To solve the above-mentioned technical problems, the present invention also provides the following technical solution: a scanning monitoring system, including the above-mentioned power plant operation monitoring auxiliary device, and further including a real-time scanning module, which is equipped with a high-performance camera for scanning every piece of information on the power plant monitoring system display to ensure that every piece of information is captured and processed in real time;

[0021] The whitelist management module allows operators to manually set up a whitelist, adding known normal information to the system for subsequent information comparison and reducing the false alarm rate.

[0022] The alarm triggering module is connected to the real-time scanning module and the whitelist management module. When the information detected by the real-time scanning module does not match the information in the whitelist management module, the alarm triggering module will immediately activate the alarm device to remind the monitoring personnel to conduct further inspection and processing.

[0023] The user interface module provides an intuitive interface for displaying real-time non-whitelist information, facilitating monitoring and operation by operators.

[0024] As a preferred embodiment of the scanning and monitoring system of the present invention, the real-time scanning module is directly connected to the power plant monitoring system display, and captures every piece of information on the display in real time through a high-performance camera, and transmits it to the whitelist management module for comparison;

[0025] As a preferred embodiment of the scanning and monitoring system of the present invention, the alarm triggering module is connected to the alarm device via an electrical signal. When non-whitelist information is detected, the alarm device is activated by sending an electrical signal to realize the alarm function.

[0026] As a preferred embodiment of the scanning and monitoring system of the present invention, the user interface module is connected to the real-time scanning module and the alarm triggering module through a data interface, and receives and displays non-whitelist information in real time, as well as receives operation instructions from operators to realize human-computer interaction;

[0027] As a preferred embodiment of the scanning and monitoring system of the present invention, the system includes a finished product effect image display module. This module displays a finished product effect image via an image output device, which is equipped with a camera at the top using computer vision technology and a larger display screen designed for displaying scrolling messages. This facilitates user understanding and use of the device.

[0028] The beneficial effects of the scanning and monitoring system described in this invention are as follows: This invention achieves real-time scanning and accurate analysis of information through advanced computer vision technology, greatly improving the practicality of the monitoring system; reducing missed reports and alarms: The application of whitelist management significantly reduces the false alarm rate, ensuring that monitoring personnel can process key information in a timely manner. Attached Figure Description

[0029] To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:

[0030] Figure 1 This is a schematic diagram of the overall auxiliary equipment for power plant operation monitoring.

[0031] Figure 2 This is a cross-sectional view of the casing of an auxiliary device for monitoring the operation of a power plant.

[0032] Figure 3 A split-section diagram of the casing structure of the auxiliary device for monitoring the operation of a power plant.

[0033] Figure 4 A schematic diagram of the disassembled structure of the fixed components of the power plant operation monitoring auxiliary device.

[0034] Figure 5 A schematic diagram of the drive component structure for a power plant operation monitoring auxiliary device.

[0035] Figure 6 A schematic diagram of the limit component structure for a power plant operation monitoring auxiliary device.

[0036] Figure 7 A cross-sectional view of the limit component structure of an auxiliary device for power plant operation monitoring.

[0037] Figure 8 for Figure 7 Enlarged view of point A in the image.

[0038] Figure label:

[0039] 100. Monitoring component; 101. Base; 102. Housing; 103. Monitoring element; 104. Fixing element; 105. Outer shell; 106. Control key; 107. Sound alarm; 108. Light alarm;

[0040] 103a, Camera; 103b, Circular plate; 103c, Filter; 103d, Hemisphere; 103e, Rack; 103f, Gear disc; 103g, Dust cover;

[0041] 104a, Mounting plate; 104b, Top plate; 104c, Limiting groove; 104d, Rotating block; 104e, Threaded groove; 104f, Fixing groove; 104g, Insert plate; 104h, Rotating rod; 104i, Fixing rod; 104j, Slot; 104k, Insert rod; 104l, Toggle plate;

[0042] 200. Adjustment component; 201. Drive component; 202. Motor; 203. Limiting component; 204. Limiting plate;

[0043] 201a, Drive gear; 201b, Driven gear; 201c, Rotating rod; 201d, Limiting cylinder;

[0044] 203a, First telescopic spring; 203b, Threaded cylinder; 203c, Second telescopic spring; 203d, Inclined block; 203e, Hinge shaft; 203f, Lower pressure groove. Detailed Implementation

[0045] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

[0046] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.

[0047] Secondly, the term "one embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that is mutually exclusive with other embodiments.

[0048] Example 1

[0049] Reference Figure 1 , Figure 3 and Figure 4 This is the first embodiment of the present invention. This embodiment provides a power plant operation monitoring auxiliary device, including a monitoring component 103 for capturing data on the power plant monitoring room display screen, thereby comparing and judging the security of the data.

[0050] Specifically, the monitoring component 100 includes a base 101 and a housing 102 disposed at the top of the base 101. A monitoring component 103 is installed at the top of the housing 102. The monitoring component 103 and the housing 102 are connected by a fastener 104, and the monitoring component 103 is located inside the outer shell 105.

[0051] Furthermore, the monitoring component 100 also includes a control key 106 disposed on the side wall of the housing 102, an audible alarm 107 disposed at the bottom of the control key 106 for alarm purposes, and a light alarm 108 disposed at the top of the control key 106, thereby improving the visibility of the warning through the audible alarm 107 and the light alarm 108.

[0052] Furthermore, the monitoring device 103 includes a camera 103a disposed inside the housing 105. A ring plate 103b is disposed on the side wall of the camera 103a, and a filter 103c is disposed on the side wall of the ring plate 103b. The filter 103c is located on the side wall of the entire ring plate 103b, and multiple filters 103c are disposed according to different types to improve the clarity of the image captured by the camera 103a.

[0053] Furthermore, the monitoring component 103 also includes a hemisphere 103d disposed on the side wall of the annular plate 103b. The camera 103a and the annular plate 103b are located inside the hemisphere 103d, and a rack 103e is provided at the end of the hemisphere 103d. Since there are two cameras 103a, the motor 202 can drive the two cameras 103a to rotate simultaneously to adjust their angles during rotation, thereby effectively improving the efficiency of the angle adjustment of the camera 103a.

[0054] Furthermore, the monitoring component 103 also includes a toothed disc 103f disposed at the bottom of the annular plate, and a dust cover 103g is installed on the outer wall of the housing 105. The dust cover 103g is matched with the camera 103a, and the filter 103c corresponds to the camera 103a. The dust cover 103g is transparent, which reduces the impact of dust on the clarity of the camera 103a. The semi-circular shape of the dust cover 103g makes it easier to clean.

[0055] Furthermore, the fastener 104 includes a mounting plate 104a disposed at the top of the housing 102, a top plate 104b mounted on the top of the mounting plate 104a, a limiting groove 104c disposed inside the mounting plate 104a, a rotating block 104d disposed inside the limiting groove 104c, a threaded groove 104e disposed inside the rotating block 104d, and a fixing groove 104f disposed at the top of the rotating block 104d.

[0056] Furthermore, the fastener 104 also includes an insert plate 104g disposed at the bottom of the housing 105. A rotating rod 104h is installed inside the insert plate 104g. A fixing rod 104i that matches the fixing groove 104f is disposed on the side wall of the rotating rod 104h. An insert rod 104k that matches the slot 104j is installed at the top of the fixing rod 104i. A toggle plate 104l is disposed inside the slot 104j.

[0057] Operation process: When using this device, first connect the housing 102 and the outer shell 105 through the fixing member 104. First, insert the insertion plate 104g into the mounting plate 104a, and the insertion plate 104g wraps around the mounting plate 104a. During the downward pressing process, the rotating rod 104h needs to align the fixing rod 104i with the fixing groove 104f. Since the rotating rod 104h is threaded, it can drive the insertion rod 104k on the rotating rod 104h to rotate during the downward pressing process. Because the insertion rod 104k can rotate when it rotates... The rotating rod 104h is fixed by engaging with the slot 104j. The rotating rod 104h also drives the rotating block 104d to rotate. After the insert rod 104k is fixed by the slot 104j, the rotating rod 104h cannot rotate and is in a fixed state. During installation, the top plate 104b is in a raised state, which can lift the motor 202 and make the motor 202 work. When it is detached from the fixed state, the motor 202 is not working, which can effectively reduce the risk of accidental contact.

[0058] Example 2

[0059] Reference Figure 2 and Figures 5-8 This is the second embodiment of the present invention. Unlike the previous embodiment, the adjustment component 200 includes a driving component 201 disposed inside the housing 105 and a limiting component 203 disposed at the top of the driving component 201 for fixing the motor 202. The top of the limiting component 203 passes through the housing 105 and is fitted with a limiting plate 204.

[0060] Furthermore, the driving component 201 includes a driving gear 201a disposed at the output end of the motor 202. The top and side walls of the driving gear 201a are provided with tooth blocks, and a driven gear 201b is installed on the top of the driving gear 201a. A rotating rod 201c is installed on the top of the driving gear 201a, and a limiting sleeve 201d is sleeved on the side wall of the rotating rod 201c.

[0061] Furthermore, the limiting member 203 includes a first telescopic spring 203a disposed on the side wall of the rotating rod 201c, a threaded cylinder 203b disposed on the side wall of the rotating rod 201c, a second telescopic spring 203c disposed on the inner wall of the threaded cylinder 203b, and the threads on the rotating rod 201c match the threads on the inner wall of the threaded cylinder 203b.

[0062] Furthermore, the limiting member 203 also includes an inclined block 203d disposed at the bottom end of the threaded cylinder 203b. The inclined block 203d is sleeved on the side wall of the hinge shaft 203e, and the side wall of the threaded cylinder 203b is provided with a pressing groove 203f that matches the inclined block 203d. The surface of the pressing groove 203f that contacts the inclined block 203d is inclined.

[0063] The rest of the structure is the same as in Example 1.

[0064] Operation process: The housing 102 is connected to the outer shell 105 via the fastener 104. First, the insert plate 104g is inserted into the mounting plate 104a, and the insert plate 104g wraps around the mounting plate 104a. During the downward pressing process, the rotating rod 104h needs to align the fixing rod 104i with the fixing groove 104f. Since the rotating rod 104h is threaded, it can drive the insert rod 104k on the rotating rod 104h to rotate during the downward pressing process. When the insert rod 104k rotates, it can engage with the slot 104j, thereby fixing the rotating rod 104h. At the same time, the rotating rod 104h can also drive the rotating block 104d to rotate. After the insert rod 104k is fixed by the slot 104j, Once the rotating rod 104h cannot rotate, it is in a fixed state. During installation, the top plate 104b is in a protruding state, which can lift the motor 202, making the motor 202 work. When it is detached from the fixed state, the motor 202 is not working, thus effectively reducing the risk of accidental contact. Then, when the camera 103a needs to be adjusted, the rotating rod 201c is pulled upward, which drives the motor 202 to move upward. When the limiting cylinder 201d contacts the outer shell 105, it cannot be pulled any further. At this time, the driving gear 201a and the driven gear 201b mesh with the rack 103e. At this time, the threaded cylinder 203b is rotated, and the rotating threaded cylinder 203b moves downward, making the inclined surface of the threaded cylinder 203b... The inclined surface of the inclined block 203d is engaged with the inclined surface of the inclined block 203d, causing the inclined block 203d to deflect and move downwards continuously until it is horizontally positioned, thus limiting the movement of the motor 202 and preventing it from moving downwards. The motor 202 is then started, driving the drive gear 201a to rotate. The rotating drive gear 201a drives the driven gear 201b to rotate, which in turn drives the rack 103e to rotate. The moving rack 103e drives the hemisphere 103d to rotate, and the hemisphere 103d also moves the camera 103a and the filter 103c simultaneously. After the camera 103a angle is adjusted, the inclined block is removed. After the limit block 203d is engaged, the first telescopic spring 203a drives the motor 202 to return to its original position, ensuring that the drive gear 201a and driven gear 201b are always engaged with the gear disk 103f. When the limit block 203d is released, it needs to be released slowly, and the motor 202 moves downward slowly to prevent damage. When the light sensor above the screen of the housing 102 detects reflection, the motor 202 is started, driving the drive gear 201a to rotate. The rotating drive gear 201a drives the gear disk 103f to rotate, and the rotating gear disk 103f drives the filter 103c on the annular plate 103b to rotate. Since the annular plate 103b is circularly wrapped around the camera 103a,This allows the corresponding filter 103c to move to the top of the camera 103a to filter out reflections and improve image quality.

[0065] Example 3

[0066] Reference Figures 1-8 This is the third embodiment of the present invention. Unlike the above embodiments, this embodiment provides a scanning monitoring system, including the above-mentioned power plant operation monitoring auxiliary device and a real-time scanning module. The module is equipped with a high-performance camera to scan every piece of information on the power plant monitoring system display, ensuring that every piece of information is captured and processed in real time.

[0067] Furthermore, the whitelist management module allows operators to manually set up a whitelist, adding known normal information to the system for subsequent information comparison, thereby reducing the false alarm rate.

[0068] Furthermore, the alarm triggering module is connected to the real-time scanning module and the whitelist management module. When the information detected by the real-time scanning module does not match the information in the whitelist management module, the alarm triggering module will immediately activate the alarm device to remind the monitoring personnel to conduct further inspection and processing.

[0069] Furthermore, the user interface module provides an intuitive interface for displaying real-time non-whitelist information, facilitating monitoring and operation by operators.

[0070] Furthermore, the real-time scanning module is directly connected to the power plant monitoring system display, and captures every piece of information on the display in real time through a high-performance camera, and transmits it to the whitelist management module for comparison;

[0071] Furthermore, the alarm triggering module is connected to the alarm device via an electrical signal. When non-whitelist information is detected, the alarm device is activated by sending an electrical signal to realize the alarm function.

[0072] Furthermore, the user interface module is connected to the real-time scanning module and the alarm triggering module through a data interface, receiving and displaying non-whitelist information in real time, as well as receiving operation instructions from operators, to realize human-computer interaction;

[0073] Furthermore, the finished product rendering display module displays the finished product rendering via an image output device. This module is equipped with a camera at the top using computer vision technology and a larger display screen designed to display scrolling messages, so that users can understand and use the device.

[0074] The rest of the structure is the same as in Example 2.

[0075] Operation process: After installation, when adjusting the camera 103a, pull the rotating rod 201c upwards. The rotating rod 201c drives the motor 202 to move upwards. When the limiting cylinder 201d contacts the outer casing 105, it cannot be pulled any further. At this time, the driving gear 201a and the driven gear 201b mesh with the rack 103e. Then, rotate the threaded cylinder 203b. The rotating threaded cylinder 203b moves downwards, so that the inclined surface of the threaded cylinder 203b is in contact with the inclined surface of the inclined block 203d, thereby causing the inclined block 203d to deflect. The downward movement continues until the inclined block 203d is in a horizontal position, limiting the motor 202 and preventing it from moving downwards. Then, start the motor 202, which drives the driving gear 103a to move downwards. Gear 201a rotates, driving gear 201b to rotate. Both gears rotate, driving rack 103e to rotate. The moving rack 103e then rotates hemisphere 103d, which in turn moves camera 103a and filter 103c simultaneously. Camera 103a scans each piece of information on the power plant monitoring system display, comparing each piece with a preset whitelist of security information. When non-whitelisted information is detected, the system immediately triggers an alarm, alerting monitoring personnel for further inspection and processing, thus reducing information omissions. The problem is that after the camera 103a angle is adjusted, and the limiting force of the inclined block 203d is removed, the motor 202 is driven back to its original position by the elastic force of the first telescopic spring 203a, so that the drive gear 201a and the driven gear 201b are always engaged with the gear disk 103f. When removing the limiting force of the inclined block 203d, it needs to be released slowly, and the motor 202 should be moved downward slowly to prevent damage. Releasing the hand will then fix the motor 202 in a long-term working state. When the light sensor above the screen of the housing 102 detects reflection, the motor 202 is started. The motor 202 drives the drive gear 201a to rotate, and the rotating drive gear 201a drives the gear disk 103f to rotate. 3f will drive the filter 103c on the annular plate 103b to rotate. Since the annular plate 103b is circularly wrapped around the camera 103a, it can drive the corresponding filter 103c to move to the top of the camera 103a to filter out the reflection and improve the imaging effect. The motor 202 has three states: First, when the housing 102 and the outer shell 105 are not working, the drive gear 201a on the motor 202 is at the bottom and does not mesh with the rack 103e, the driven gear 201b and the gear disk 103f. Second, in the normal working state, the drive gear 201a meshes with the gear disk 103f. Third, in the adjustment state, the drive gear 201a meshes with the rack 103e and the driven gear 201b.

[0076] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible (e.g., changes in the size, dimensions, structure, shape, and proportions of various elements, as well as parameter values ​​(e.g., temperature, pressure, etc.), mounting arrangements, use of materials, color, orientation, etc.) without substantially departing from the novel teachings and advantages of the subject matter described in this application). For example, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise altered, and the nature or number or position of discrete elements may be changed or altered. Therefore, all such modifications are intended to be included within the scope of the invention. The order or sequence of any process or method steps may be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure described herein that performs the function, and not only structurally equivalent but also equivalent in structure. Other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments without departing from the scope of the invention. Therefore, the present invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims.

[0077] Furthermore, in order to provide a concise description of exemplary embodiments, not all features of actual embodiments (i.e., those features that are not relevant to the best mode of carrying out the invention as currently considered, or those features that are not relevant to implementing the invention) may be omitted.

[0078] It should be understood that numerous specific implementation decisions can be made during the development of any practical implementation, such as in any engineering or design project. Such development efforts may be complex and time-consuming, but for those skilled in the art who benefit from this disclosure, the development effort will be a routine work of design, manufacturing, and production without requiring much experimentation.

[0079] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.

Claims

1. A power plant operation monitoring auxiliary device, characterized in that: include, The monitoring component (100) includes a base (101) and a housing (102) disposed at the top of the base (101). A monitoring component (103) is installed at the top of the housing (102). The monitoring component (103) and the housing (102) are connected by a fastener (104), and the monitoring component (103) is located inside the outer shell (105). The adjustment assembly (200) includes a drive member (201) disposed inside the housing (105) and a limiting member (203) disposed at the top of the drive member (201) for fixing the motor (202). The top of the limiting member (203) passes through the housing (105) and is fitted with a limiting plate (204).

2. The power plant operation monitoring auxiliary device as described in claim 1, characterized in that: The monitoring component (100) also includes a control key (106) disposed on the side wall of the housing (102), a sound alarm (107) disposed at the bottom of the control key (106) for alarm purposes, and a light alarm (108) disposed at the top of the control key (106).

3. The power plant operation monitoring auxiliary device as described in claim 2, characterized in that: The monitoring device (103) includes a camera (103a) disposed inside the housing (105), the side wall of the camera (103a) is provided with an annular plate (103b), and the side wall of the annular plate (103b) is provided with a filter (103c).

4. The power plant operation monitoring auxiliary device as described in claim 3, characterized in that: The monitoring device (103) also includes a hemisphere (103d) disposed on the side wall of the annular plate (103b), wherein the camera (103a) and the annular plate (103b) are located inside the hemisphere (103d), and a rack (103e) is provided at the end of the hemisphere (103d).

5. The power plant operation monitoring auxiliary device as described in claim 4, characterized in that: The monitoring device (103) also includes a toothed disc (103f) disposed at the bottom end of the annular plate. A dust cover (103g) is installed on the outer wall of the housing (105). The dust cover (103g) matches the camera (103a), and the filter (103c) corresponds to the camera (103a).

6. The power plant operation monitoring auxiliary device as described in claim 5, characterized in that: The fastener (104) includes a mounting plate (104a) disposed at the top of the housing (102), a top plate (104b) is mounted on the top of the mounting plate (104a), a limiting groove (104c) is installed inside the mounting plate (104a), a rotating block (104d) is installed inside the limiting groove (104c), a threaded groove (104e) is provided inside the rotating block (104d), and a fixing groove (104f) is provided at the top of the rotating block (104d).

7. The power plant operation monitoring auxiliary device as described in claim 6, characterized in that: The fastener (104) further includes an insert plate (104g) disposed at the bottom of the housing (105). A rotating rod (104h) is installed inside the insert plate (104g). A fixing rod (104i) matching the fixing groove (104f) is provided on the side wall of the rotating rod (104h). An insert rod (104k) matching the slot (104j) is installed at the top of the fixing rod (104i). A toggle plate (104l) is disposed inside the slot (104j).

8. The power plant operation monitoring auxiliary device as described in claim 7, characterized in that: The driving component (201) includes a driving gear (201a) disposed at the output end of the motor (202). The top end and side wall of the driving gear (201a) are provided with tooth blocks, and a driven gear (201b) is installed on the top end of the driving gear (201a). A rotating rod (201c) is installed on the top end of the driving gear (201a), and a limiting sleeve (201d) is sleeved on the side wall of the rotating rod (201c).

9. The power plant operation monitoring auxiliary device as described in claim 8, characterized in that: The limiting member (203) includes a first telescopic spring (203a) disposed on the side wall of the rotating rod (201c), a threaded cylinder (203b) disposed on the side wall of the rotating rod (201c), a second telescopic spring (203c) disposed on the inner wall of the threaded cylinder (203b), and the threads on the rotating rod (201c) match the threads on the inner wall of the threaded cylinder (203b); The limiting member (203) also includes an inclined block (203d) disposed at the bottom end of the threaded cylinder (203b). The inclined block (203d) is sleeved on the side wall of the hinge shaft (203e), and the side wall of the threaded cylinder (203b) is provided with a downward pressing groove (203f) that matches the inclined block (203d). The surface of the downward pressing groove (203f) that contacts the inclined block (203d) is inclined.

10. A scanning monitoring system, characterized in that: The power plant operation monitoring auxiliary device, including any one of claims 1 to 9, further includes: The real-time scanning module is equipped with a high-performance camera to scan every piece of information on the power plant monitoring system display, ensuring that every piece of information is captured and processed in real time. The whitelist management module allows operators to manually set up a whitelist, adding known normal information to the system for subsequent information comparison and reducing the false alarm rate. The alarm triggering module is connected to the real-time scanning module and the whitelist management module. When the information detected by the real-time scanning module does not match the information in the whitelist management module, the alarm triggering module will immediately activate the alarm device to remind the monitoring personnel to conduct further inspection and processing. The user interface module provides an intuitive interface for displaying real-time non-whitelist information, facilitating monitoring and operation by operators. The real-time scanning module is directly connected to the power plant monitoring system display. It captures every piece of information on the display in real time through a high-performance camera and transmits it to the whitelist management module for comparison. The alarm triggering module is connected to the alarm device via an electrical signal. When non-whitelist information is detected, the alarm device is activated by sending an electrical signal to realize the alarm function. The user interface module is connected to the real-time scanning module and the alarm triggering module through a data interface, and receives and displays non-whitelist information in real time, as well as receiving operation instructions from operators to realize human-computer interaction; The finished product rendering display module displays finished product renderings via an image output device. This module is equipped with a camera at the top using computer vision technology and a larger display screen designed to display scrolling messages, so that users can understand and use the device.