A power station intelligent co-driver platform architecture adaptation debugging system and method
Through the collaborative efforts of the architecture adaptation layer, intelligent debugging layer, data interaction layer, monitoring and early warning layer, and operation and maintenance management layer, the compatibility and automation issues in the architecture adaptation and debugging of the power plant intelligent co-pilot platform have been resolved, achieving efficient and stable adaptation and debugging of the power plant intelligent co-pilot platform.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- XIAN THERMAL POWER RES INST CO LTD
- Filing Date
- 2026-03-26
- Publication Date
- 2026-06-19
AI Technical Summary
Existing intelligent co-pilot platform architecture adaptation and debugging technologies for power plants suffer from poor compatibility, high reliance on manual labor, low efficiency, high maintenance costs, lack of real-time monitoring and fault location functions, and difficulty in achieving full-link data interaction and automatic adaptation.
An architecture adaptation layer parses heterogeneous communication protocols and establishes standardized connection links; an intelligent debugging layer automatically executes the adaptation process and optimizes strategies; a data interaction layer ensures secure data transmission; a monitoring and early warning layer monitors faults in real time and issues early warnings; an operations and maintenance management layer records debugging data and provides contingency plan references; and a dynamic adaptation unit senses changes in equipment and automatically adjusts strategies.
It achieves precise adaptation and efficient debugging across devices and protocols, reduces reliance on manual intervention, shortens the debugging cycle, improves system stability and maintainability, and ensures stable platform operation.
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Figure CN122246993A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of intelligent control technology for power plants, specifically to an intelligent co-pilot platform architecture adaptation and debugging system and method for power plants. Background Technology
[0002] As a core device for improving power plant operating efficiency and ensuring operational safety, the intelligent co-pilot platform needs to achieve deep compatibility and integration with the power plant's existing control system, various sensing terminals, and actuators. Existing adaptation and debugging technologies have significant shortcomings: First, the existing equipment in power plants comes in a wide variety of brands and models, with inconsistent communication protocols and data formats, resulting in poor compatibility with the intelligent co-pilot platform architecture and difficulty in achieving end-to-end data interaction. Second, adaptation and debugging largely rely on manual parameter configuration and link verification, which is cumbersome, inefficient, and prone to adaptation failures due to human error. Third, there is a lack of dynamic adaptation mechanisms; when power plant equipment is updated or operating conditions change, the platform architecture cannot automatically adjust its adaptation strategy, requiring a complete overhaul of the debugging process, leading to high maintenance costs. Fourth, the lack of real-time monitoring and fault location functions during debugging makes it difficult to quickly identify adaptation anomalies, extending the debugging cycle. Fifth, the existing system lacks a support library of adaptation contingency plans, leaving no reference for complex adaptation scenarios, easily leading to adaptation logic conflicts and affecting the platform's operational stability. Summary of the Invention
[0003] The purpose of this invention is to provide a power plant intelligent co-pilot platform architecture adaptation and debugging system to solve the problem of poor platform stability after adaptation in the prior art.
[0004] To address the aforementioned problems, this invention proposes a power plant intelligent co-pilot platform architecture adaptation and debugging system. The technical solution adopted is as follows: A power plant intelligent co-pilot platform architecture adaptation and debugging system includes: an architecture adaptation layer, an intelligent debugging layer, a data interaction layer, a monitoring and early warning layer, and an operation and maintenance management layer that sequentially establish communication connections; wherein... The architecture adaptation layer is used to parse heterogeneous communication protocols and adapt to devices of different brands and models, and to establish a standardized interface link. The intelligent debugging layer is used to automatically execute the adaptation debugging process based on the standardized docking link and optimize the adaptation strategy based on the debugging results. The data interaction layer is used to ensure the secure, real-time, and complete transmission of interactive data between different layers during the adaptation and debugging process. The monitoring and early warning layer is used to monitor the debugging status in real time, locate fault points, and issue early warnings. The operation and maintenance management layer is used to record data throughout the entire adaptation and debugging process and to provide contingency plans for complex adaptation scenarios.
[0005] Furthermore, the architecture adaptation layer includes: The protocol parsing unit is used to parse various heterogeneous communication protocols of the power plant's original equipment and systems and convert them into a unified data format; The equipment adapter unit is used to adapt to different brands and models of power plant sensing equipment, actuators and control systems, and to establish a standardized interface link based on a unified data format.
[0006] Furthermore, the protocol parsing unit includes an extensible protocol library, which is used to adapt to the exclusive communication protocols of newly added equipment in the power plant by adding new communication protocol parsing rules.
[0007] Furthermore, the intelligent debugging layer includes: The automated debugging unit is used to automatically initiate verification of the adaptation links in the standardized docking link, data interaction testing and functional linkage verification according to the preset debugging process module, and generate debugging results. The adaptation strategy optimization unit is used to dynamically adjust adaptation parameters and link configuration based on debugging results.
[0008] Furthermore, the data interaction layer includes: The data encryption unit is used to encrypt interactive data during the adaptation and debugging process; The data forwarding unit is used to achieve real-time and complete forwarding of interactive data between different levels.
[0009] Furthermore, the monitoring and early warning layer includes: The status monitoring unit is used to collect link status, data interaction status and device operating status in real time during the adaptation and debugging process, and to obtain abnormal status data. The fault location unit is used to locate the appropriate fault point and fault type based on abnormal state data, and generate fault troubleshooting guidelines. The early warning unit is used to issue an early warning when the status monitoring unit detects an adaptation anomaly or a risk of failure.
[0010] Furthermore, the operations and maintenance management layer includes: The debug log unit is used to record data throughout the entire adaptation and debugging process; The adaptation plan unit is used to store adaptation plans for different power plant scenarios and different equipment combinations, forming an adaptation plan library.
[0011] Furthermore, the power station intelligent co-pilot platform architecture adaptation and debugging system also includes: The dynamic adaptation unit is used to obtain the status of power plant equipment iteration updates or changes in operating conditions, and to automatically trigger the adaptation verification process and adjust the adaptation strategy based on the adaptation plan library when power plant equipment iteration updates or operating conditions change.
[0012] Furthermore, the dynamic adaptation unit includes: The equipment operating condition change sensing module is used to obtain the status of power plant equipment iteration updates or changes in operating conditions; The automatic verification and strategy adjustment module is used to automatically trigger the adaptation verification process and adjust the adaptation strategy based on the adaptation plan library when the power plant equipment is updated or the operating conditions change.
[0013] This invention also proposes a method for adapting and debugging a power plant intelligent co-pilot platform architecture, based on the aforementioned power plant intelligent co-pilot platform architecture adaptation and debugging system, comprising the following steps: Step S1: The architecture adaptation layer parses heterogeneous communication protocols and adapts them to devices of different brands and models, establishing a standardized interface link; at the same time, the data interaction layer starts encryption and transmission services to ensure the secure, real-time, and complete transmission of interactive data during the adaptation and debugging process. In step S2, the intelligent debugging layer automatically executes the adaptation debugging process based on the standardized docking link and optimizes the adaptation strategy based on the debugging results; at the same time, the monitoring and early warning layer monitors the debugging status in real time, locates the fault point and issues an early warning; the operation and maintenance management layer records the data of the entire debugging process and provides contingency plan references for complex adaptation scenarios.
[0014] Compared with the prior art, the present application has the following beneficial effects: This invention is an improved version. Through an architecture adaptation layer, it achieves compatibility and adaptation with different brands, models, and various communication protocols, establishing a standardized interface link and solving the problems of poor compatibility and difficulty in full-link data interaction in existing technologies. Simultaneously, the intelligent debugging layer automates the adaptation and debugging process, achieving fully unmanned debugging and dynamically optimizing the adaptation logic. Combined with the operation and maintenance management layer's recording of the entire debugging process data and provision of contingency plans for complex adaptation scenarios, it reduces reliance on manual labor, shortens the debugging cycle, and solves the problems of cumbersome, inefficient, and unreliable manual operations. The power plant intelligent co-pilot platform architecture adaptation and debugging system of this application establishes communication connections sequentially through the architecture adaptation layer, intelligent debugging layer, data interaction layer, monitoring and early warning layer, and operation and maintenance management layer. This collaboratively achieves architecture adaptation and automated debugging between the power plant intelligent co-pilot platform and existing power plant equipment and systems, enabling precise and efficient cross-device and cross-protocol adaptation and debugging. This ensures the stability of the platform after adaptation, realizing automation, intelligence, traceability, and self-adaptation of the power plant intelligent co-pilot platform adaptation and debugging, significantly shortening the debugging cycle, reducing reliance on human intervention, and improving system stability and maintainability.
[0015] The architecture adaptation layer includes: The protocol parsing unit is used to parse various heterogeneous communication protocols of the power plant's original equipment and systems, and convert them into a unified data format, thereby eliminating communication barriers between different manufacturers and different types of equipment and reducing the workload of customized development. The equipment adapter unit is used to adapt to power plant sensing equipment, actuators and control systems of different brands and models. Based on a unified data format, it establishes a standardized interface link, providing a consistent interface foundation for subsequent debugging, data transmission and monitoring, and reducing integration complexity.
[0016] The protocol parsing unit includes an extensible protocol library, used to adapt to the exclusive communication protocols of newly added equipment in the power plant by adding new communication protocol parsing rules. This extensible protocol library supports adding new protocol parsing rules online or offline, allowing access to new models or manufacturers of equipment without redesigning the system architecture. This avoids the need to modify core code every time new equipment is added; adaptation is completed simply by updating the protocol library, reducing maintenance costs. It is suitable for scenarios with frequent upgrades or replacements of power plant equipment, ensuring the long-term availability of the power plant intelligent co-pilot platform architecture adaptation and debugging system.
[0017] The intelligent debugging layer includes: The automated debugging unit is used to automatically initiate verification of the adaptation links in the standardized docking link, data interaction testing and functional linkage verification according to the preset debugging process module, and generate debugging results. The adaptation strategy optimization unit is used to dynamically adjust adaptation parameters and link configuration based on debugging results.
[0018] The automated debugging unit can complete the entire unmanned debugging process from link establishment and data interaction to functional linkage based on the preset debugging process module, without the need for manual intervention, which greatly shortens the debugging cycle and improves automation, debugging efficiency and debugging accuracy.
[0019] The monitoring and early warning layer includes: The status monitoring unit is used to collect link status, data interaction status and device operating status in real time during the adaptation and debugging process, and to obtain abnormal status data. The fault location unit is used to locate the appropriate fault point and fault type based on abnormal state data, and generate fault troubleshooting guidelines. The early warning unit is used to issue early warnings when the status monitoring unit detects adaptation anomalies or potential fault risks. The monitoring and early warning layer provides real-time monitoring, can quickly locate fault points, generate troubleshooting guidelines, and achieve proactive early warning.
[0020] The operations and maintenance management layer includes: The debug log unit is used to record data throughout the entire adaptation and debugging process, enabling traceability of the debugging process; The adaptation plan unit is used to store adaptation plans for different power plant scenarios and different equipment combinations, forming an adaptation plan library to provide a reference for adaptation of complex scenarios and different equipment.
[0021] The power station intelligent co-pilot platform architecture adaptation and debugging system also includes: The dynamic adaptation unit is used to acquire the status of power plant equipment iteration updates or changes in operating conditions. When power plant equipment is updated or operating conditions change, it automatically triggers the adaptation verification process and adjusts the adaptation strategy based on the adaptation plan library. The power plant intelligent co-pilot platform architecture adaptation and debugging system uses the dynamic adaptation unit to perceive equipment iteration and operating condition changes in real time, automatically triggering adaptation verification and strategy adjustment without the need for full process readjustment. Combined with the status monitoring, fault location, and early warning unit of the monitoring and early warning layer, it achieves accurate anomaly detection and timely reminders, reduces maintenance costs, and ensures stable operation. Attached Figure Description
[0022] Figure 1 This is a structural schematic diagram of the power plant intelligent co-pilot platform architecture adaptation and debugging system of the present invention.
[0023] Figure 2 This is a flowchart illustrating the power plant intelligent co-pilot platform architecture adaptation and debugging method of the present invention. Detailed Implementation
[0024] The embodiments of this application are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain this application, and should not be construed as limiting this application.
[0025] It should be noted that the terms "first," "second," etc., in the specification, claims, and accompanying drawings of this invention are used to distinguish similar objects and are not necessarily used to describe a specific order or sequence. It should be understood that such data can be interchanged where appropriate so that the embodiments of the invention described herein can be implemented in orders other than those illustrated or described herein. Furthermore, the terms "comprising" and "having," and any variations thereof, are intended to cover a non-exclusive inclusion; for example, a process, method, system, product, or apparatus that comprises a series of steps or units is not necessarily limited to those steps or units explicitly listed, but may include other steps or units not explicitly listed or inherent to such processes, methods, products, or apparatus.
[0026] The following is combined Figure 1 This application provides a detailed description of a power plant intelligent co-pilot platform architecture adaptation and debugging system.
[0027] In this embodiment, as Figure 1 As shown, this application provides a power plant intelligent co-pilot platform architecture adaptation and debugging system, including: an architecture adaptation layer, an intelligent debugging layer, a data interaction layer, a monitoring and early warning layer, and an operation and maintenance management layer that establish communication connections in sequence.
[0028] The architecture adaptation layer is used to parse heterogeneous communication protocols and adapt to devices of different brands and models, establishing standardized interface links. Specifically, the architecture adaptation layer includes: a protocol parsing unit, used to parse various heterogeneous communication protocols of the power plant's existing equipment and systems and convert them into a unified data format; and a device adaptation unit, used to adapt to power plant sensing devices, actuators, and control systems of different brands and models, and establish standardized interface links based on the unified data format. The protocol parsing unit parses various heterogeneous communication protocols of the power plant's existing equipment and systems and converts them into a unified data format, eliminating communication barriers between different manufacturers and types of equipment and reducing the workload of customized development. The device adaptation unit adapts to power plant sensing devices, actuators, and control systems of different brands and models, improving the system's compatibility with both new and old equipment; and the standardized interface links established based on the unified data format provide a consistent interface foundation for subsequent debugging, data transmission, and monitoring, reducing integration complexity.
[0029] In another implementation, the protocol parsing unit includes an extensible protocol library for adapting to the proprietary communication protocols of newly added equipment in the power plant by adding new protocol communication parsing rules. This extensible protocol library supports adding new protocol parsing rules online or offline, allowing access to new models or manufacturers of equipment without redesigning the system architecture. This avoids the need to modify core code every time new equipment is added; adaptation is completed simply by updating the protocol library, reducing maintenance costs. It is suitable for scenarios with frequent upgrades or replacements of power plant equipment, ensuring the long-term availability of the power plant intelligent co-pilot platform architecture adaptation and debugging system.
[0030] The intelligent debugging layer is used to automatically execute adaptation debugging processes based on standardized interface links and optimize adaptation strategies based on debugging results. Specifically, the intelligent debugging layer includes: an automated debugging unit, which automatically initiates verification of adaptation links, data interaction tests, and functional linkage verification in the standardized interface links according to preset debugging process modules, and generates debugging results; and an adaptation strategy optimization unit, which dynamically adjusts adaptation parameters and link configurations based on debugging results to optimize adaptation logic. The automated debugging unit, based on preset debugging processes, completes fully unmanned debugging from link establishment and data interaction to functional linkage, requiring no manual intervention, significantly shortening the debugging cycle, and improving automation, debugging efficiency, and debugging accuracy. The adaptation strategy optimization unit, based on debugging results, dynamically adjusts adaptation parameters and link configurations to optimize adaptation logic, enabling the system to gradually approach its optimal working state during operation.
[0031] The data interaction layer is used to ensure the secure, real-time, and complete transmission of interactive data during the adaptation and debugging process. Specifically, the data interaction layer includes: a data encryption unit, used to encrypt the interactive data during the adaptation and debugging process to ensure data transmission security; and a data forwarding unit, used to achieve real-time and complete forwarding of interactive data between each layer, ensuring the real-time performance and integrity of data transmission, so that data is not lost or out of order during transmission, providing a reliable basis for debugging and monitoring.
[0032] The monitoring and early warning layer is used to monitor the debugging status in real time, locate fault points, and issue early warnings. Specifically, the monitoring and early warning layer includes: a status monitoring unit, used to collect link status, data interaction status, and equipment operating status in real time during the adaptation and debugging process, and obtain abnormal status data; a fault location unit, used to locate adaptation fault points and fault types based on abnormal status data, and generate fault troubleshooting guidelines to shorten fault handling time; and an early warning unit, used to issue early warning prompts when the status monitoring unit detects adaptation anomalies or fault risks, thereby improving system security. Specifically, when the status monitoring unit detects adaptation anomalies or fault risks, the early warning unit issues early warning prompts via audio-visual, pop-up, or message push methods, and simultaneously pushes the early warning prompts to the operation and maintenance terminal.
[0033] In one specific implementation, the monitoring and early warning layer also includes an audio-visual pop-up early warning module, which is used to issue early warning prompts through audio-visual means, pop-ups, or message push when the status monitoring unit in the early warning unit detects an adaptation anomaly or fault risk.
[0034] In another specific implementation, the power plant intelligent co-pilot platform architecture adaptation and debugging system also includes an operation and maintenance terminal push module, which is used to simultaneously push early warning prompts issued by sound and light, pop-up windows or message push methods to the operation and maintenance terminal.
[0035] The operations and maintenance (O&M) management layer is used to record data throughout the entire adaptation and debugging process and provide contingency plans for complex adaptation scenarios. The O&M management layer includes: a debugging log unit, used to record data throughout the entire adaptation and debugging process to ensure traceability of the debugging process; and an adaptation contingency plan unit, used to store adaptation contingency plans for different power plant scenarios and different equipment combinations, forming an adaptation contingency plan library to provide reference for complex scenarios and adaptation to different equipment.
[0036] In another implementation, the power plant intelligent co-pilot platform architecture adaptation and debugging system also includes: The dynamic adaptation unit is used to acquire the status of power plant equipment iteration updates or changes in operating conditions. When power plant equipment is updated or operating conditions change, it automatically triggers the adaptation verification process and adjusts the adaptation strategy based on the adaptation plan library. Through this dynamic adaptation unit, the system can automatically adjust with equipment updates and changes in the operating environment, reducing manual intervention and enhancing adaptability; ensuring that the system can still maintain efficient and stable commissioning and operation after equipment upgrades or changes in operating conditions; at the same time, the automatic triggering of the adaptation verification process and adjustment of the adaptation strategy can be completed quickly, reducing production interruptions caused by equipment changes.
[0037] Specifically, the dynamic adaptation unit includes: an equipment operating condition change sensing module, used to obtain the status of power plant equipment iteration updates or changes in operating conditions, providing a basis for subsequent adjustments; and an automatic verification and strategy adjustment module, used to automatically trigger the adaptation verification process and adjust the adaptation strategy based on the adaptation plan library when power plant equipment iterates or its operating conditions change, without having to manually debug the entire process again, improving response speed, and enabling the system to form a closed loop from sensing changes in equipment or environment to automatic adjustment, thereby improving the system's intelligence level.
[0038] This application also provides a method for adapting and debugging the architecture of a power plant intelligent co-pilot platform, such as... Figure 2 As shown, the adaptation and debugging system based on the above-mentioned power plant intelligent co-pilot platform architecture includes the following steps: Step S1: The architecture adaptation layer parses heterogeneous communication protocols and adapts them to devices of different brands and models, establishing a standardized interface link; at the same time, the data interaction layer starts encryption and transmission services to ensure the secure, real-time, and complete transmission of interactive data during the adaptation and debugging process. In step S2, the intelligent debugging layer automatically executes the adaptation debugging process based on the standardized docking link and optimizes the adaptation strategy based on the debugging results; at the same time, the monitoring and early warning layer monitors the debugging status in real time, locates the fault point and issues an early warning; the operation and maintenance management layer records the data of the entire debugging process and provides contingency plan references for complex adaptation scenarios.
[0039] In summary, the intelligent co-pilot platform architecture adaptation and debugging system for this power station operates as follows: First, the architecture adaptation layer initializes the system; the protocol parsing unit unifies the protocol format; and the device adaptation unit establishes the connection link. The data interaction layer initiates encryption and forwarding services; the intelligent debugging layer automatically debugs and optimizes the adaptation logic according to a preset process; the monitoring and early warning layer monitors the status in real time, triggering early warnings and locating faults when anomalies occur; the operation and maintenance management layer records logs and updates the contingency plan library; and the dynamic adaptation unit senses changes in equipment or operating conditions and automatically adjusts the adaptation strategy. The entire process requires minimal manual intervention, efficiently adapting to various power station scenarios and ensuring stable platform operation.
[0040] Here, those skilled in the art will understand that the specific operations in the above-mentioned power station intelligent co-pilot platform architecture adaptation and debugging method have been referenced above. Figure 1 The description of the power plant intelligent co-pilot platform architecture adaptation and debugging system is detailed here.
[0041] The above description is merely a preferred embodiment of the present invention and is not intended to limit the present invention. The scope of patent protection of the present invention shall be determined by the claims. Similarly, any equivalent structural changes made based on the description and drawings of the present invention shall also be included within the scope of protection of the present invention.
Claims
1. An intelligent co-driver platform architecture adaptation debugging system for a power station, characterized in that, include: The architecture adaptation layer, intelligent debugging layer, data interaction layer, monitoring and early warning layer, and operation and maintenance management layer are established sequentially for communication connections; among them, The architecture adaptation layer is used to parse heterogeneous communication protocols and adapt to devices of different brands and models, and to establish a standardized interface link. The intelligent debugging layer is used to automatically execute the adaptation debugging process based on the standardized docking link and optimize the adaptation strategy based on the debugging results. The data interaction layer is used to ensure the secure, real-time, and complete transmission of interactive data between different layers during the adaptation and debugging process. The monitoring and early warning layer is used to monitor the debugging status in real time, locate fault points, and issue early warnings. The operation and maintenance management layer is used to record data throughout the entire adaptation and debugging process and to provide contingency plans for complex adaptation scenarios. 2.The power station intelligent co-pilot platform architecture adaptation debugging system according to claim 1, characterized in that, The architecture adaptation layer includes: The protocol parsing unit is used to parse various heterogeneous communication protocols of the power plant's original equipment and systems and convert them into a unified data format; The equipment adapter unit is used to adapt to different brands and models of power plant sensing equipment, actuators and control systems, and to establish a standardized interface link based on a unified data format. 3.The power station intelligent co-pilot platform architecture adaptation debugging system of claim 2, characterized in that, The protocol parsing unit includes an extensible protocol library, which is used to adapt to the exclusive communication protocols of newly added equipment in the power plant by adding new communication protocol parsing rules.
4. The power station intelligent co-pilot platform architecture adaptation debugging system of claim 1, wherein, The intelligent debugging layer includes: The automated debugging unit is used to automatically initiate verification of the adaptation links in the standardized docking link, data interaction testing and functional linkage verification according to the preset debugging process module, and generate debugging results. The adaptation strategy optimization unit is used to dynamically adjust adaptation parameters and link configuration based on debugging results.
5. The power plant intelligent co-pilot platform architecture adaptation and debugging system according to claim 1, characterized in that, The data interaction layer includes: The data encryption unit is used to encrypt interactive data during the adaptation and debugging process; The data forwarding unit is used to achieve real-time and complete forwarding of interactive data between different levels.
6. The power plant intelligent co-pilot platform architecture adaptation and debugging system according to claim 1, characterized in that, The monitoring and early warning layer includes: The status monitoring unit is used to collect link status, data interaction status and device operating status in real time during the adaptation and debugging process, and to obtain abnormal status data. The fault location unit is used to locate the appropriate fault point and fault type based on abnormal state data, and generate fault troubleshooting guidelines. The early warning unit is used to issue an early warning when the status monitoring unit detects an adaptation anomaly or a risk of failure.
7. The power plant intelligent co-pilot platform architecture adaptation and debugging system according to claim 1, characterized in that, The operations and maintenance management layer includes: The debug log unit is used to record data throughout the entire adaptation and debugging process; The adaptation plan unit is used to store adaptation plans for different power plant scenarios and different equipment combinations, forming an adaptation plan library.
8. The power plant intelligent co-pilot platform architecture adaptation and debugging system according to claim 7, characterized in that, The power station intelligent co-pilot platform architecture adaptation and debugging system also includes: The dynamic adaptation unit is used to obtain the status of power plant equipment iteration updates or changes in operating conditions, and when the power plant equipment iterates or the operating conditions change, it automatically triggers the adaptation verification process and adjusts the adaptation strategy based on the adaptation plan library.
9. The power plant intelligent co-pilot platform architecture adaptation and debugging system according to claim 8, characterized in that, The dynamic adaptation unit includes: The equipment operating condition change sensing module is used to obtain the status of power plant equipment iteration updates or changes in operating conditions; The automatic verification and strategy adjustment module is used to automatically trigger the adaptation verification process and adjust the adaptation strategy based on the adaptation plan library when the power plant equipment is updated or the operating conditions change.
10. A method for adapting and debugging an intelligent co-pilot platform architecture for a power station, characterized in that, The power plant intelligent co-pilot platform architecture adaptation and debugging system according to any one of claims 1-9 includes the following steps: Step S1: The architecture adaptation layer parses heterogeneous communication protocols and adapts them to devices of different brands and models, establishing a standardized interface link; at the same time, the data interaction layer starts encryption and transmission services to ensure the secure, real-time, and complete transmission of interactive data during the adaptation and debugging process. In step S2, the intelligent debugging layer automatically executes the adaptation and debugging process based on the standardized interface link and optimizes the adaptation strategy based on the debugging results; at the same time, the monitoring and early warning layer monitors the debugging status in real time, locates the fault point and issues an early warning. The operations and maintenance management team records data throughout the entire debugging process and provides contingency plans for complex adaptation scenarios.