融合LLM-RAG-KG的电力生产安全事故问答大模型*

doi:10.16265/j.cnki.issn1003-3033.2026.03.0874

中国安全科学学报 ›› 2026, Vol. 36 ›› Issue (3): 66-73.doi: 10.16265/j.cnki.issn1003-3033.2026.03.0874

融合LLM-RAG-KG的电力生产安全事故问答大模型^*

晋良海¹^,²(), 张倩²^,³, 徐童欣¹^,², 陈云¹^,², 彭仲文⁴

¹ 三峡大学水电工程施工与管理湖北省重点实验室, 湖北宜昌 443002
² 三峡大学水利与环境学院, 湖北宜昌 443002
³ 三峡大学经济与管理学院, 湖北宜昌 443002
⁴ 中国铁建大桥工程局集团有限公司, 天津 300300

收稿日期:2025-09-10 修回日期:2025-12-15 出版日期:2026-03-31
作者简介:
晋良海 (1973—),男,四川简阳人,教授,博士生导师,全国水利工程专业学位优秀指导教师,主要从事安全工效学研究。 E-mail: jinlianghai@ctgu.edu.cn。
张倩,工程师。
基金资助:
国家自然科学基金资助(52179136); 教育部人文社科规划基金资助(21YJA630038); 中国铁建大桥工程局集团有限公司科研项目(SDHZ2022012); 湖北省自然科学基金资助(2024AFD153)

A large model for analyzing power production safety accidents integrating LLM, RAG and KG

JIN Lianghai¹^,²(), ZHANG Qian²^,³, XU Tongxin¹^,², CHEN Yun¹^,², PENG Zhongwen⁴

¹ Hubei Key Laboratory of Construction and Management in Hydropower Engineering, China Three Gorges University, Yichang Hubei 443002, China
² College of Hydraulic & Environmental Engineering, China Three Gorges University, Yichang Hubei 443002, China
³ School of Economics and Management, China Three Gorges University, Yichang Hubei 443002, China
⁴ China Railway Construction Bridge Engineering Group Co., Ltd., Tianjin 300300, China

Received:2025-09-10 Revised:2025-12-15 Published:2026-03-31

摘要/Abstract

摘要：

为解决传统分析方法在面对电力系统多因素非线性交互的复杂特性时存在专业知识整合不足、因果推理可解释性弱等固有局限,提出一种融合大型语言模型(LLM)、检索增强生成(RAG)和知识图谱(KG)的电力生产安全事故分析大模型;构建包含知识检索、知识推理、答案生成与效果评估4个核心模块框架:基于RAG技术从专业文本中精准检索相关知识,利用KG结构化推理事故实体和关系,以弥补检索盲区;通过LLM生成专业、可解释的事故因果分析答案,通过主观专家评分与自动评估指标(ROUGE)、双语替换学习(BLEU)等客观指标全面评估系统。结果表明:在电力生产安全事故分析场景中,RAG 与 KG 的知识增强技术对具备一定规模参数的基础模型有普适性性能提升,能帮助模型精准捕捉设备故障传导链等专业关联,提升事故致因挖掘与结果演化推理质量;DeepSeek-R1、Qwen2.5-72B等大模型在该模式下解析专业术语、梳理多因素关联的准确性显著提高,其中 DeepSeek-R1 综合评分达 4.05 分,更满足领域精度要求;增强效果存在模型能力阈值,Qwen2.5-72B 增强后能高效解析跨区域电网故障联动等复杂逻辑,且平衡性能与部署成本,适配企业实际需求,而 Qwen2.5-14B 等小模型因基础推理能力有限,引入外部知识后难处理专业信息,性能下降,无法满足专业性要求。

关键词: 大型语言模型(LLM), 检索增强生成(RAG), 知识图谱(KG), 电力生产安全事故, 事故分析, DeepSeek-R1

Abstract:

In order to address the inherent limitations of traditional analysis methods—such as insufficient integration of professional knowledge and weak interpretability of causal reasoning—when dealing with the complex characteristics of multi-factor nonlinear interactions in power systems, a large model for power production safety accident analysis was proposed that integrates LLM, RAG, and KG. A framework with four core modules was built: knowledge retrieval, knowledge reasoning, answer generation, and performance evaluation. RAG technology was used to accurately retrieve relevant knowledge from professional texts, and KG was leveraged for structured reasoning on accident entities and relationships to make up for retrieval blind spots. Finally, LLM was employed to generate professional and interpretable answers for accident causal analysis. The study comprehensively evaluated the system through subjective expert scoring and objective metrics like ROUGE and BLEU, and results show that in the scenario of power production safety accident analysis, the knowledge enhancement technology of RAG and KG provides universal performance improvement for basic models with a certain parameter scale—it helps models accurately capture professional correlations such as equipment fault transmission chains and enhances the quality of accident cause mining and result evolution reasoning. Large models including DeepSeek-R1 and Qwen2.5-72B significantly improved in the accuracy of parsing professional terms and organizing multi-factor correlations under this mode, among which DeepSeek-R1 achieved a comprehensive score of 4.05, better meeting the precision requirements of the field; meanwhile, there is a model capability threshold for the enhancement effect: after enhancement, Qwen2.5-72B can efficiently parse complex logics like cross-regional power grid fault linkage, balances performance and deployment costs, and is suitable for enterprises' practical needs, while smaller models such as Qwen2.5-14B, due to limited basic reasoning capabilities, fail to process professional information effectively after introducing external knowledge, leading to performance degradation and inability to meet professional requirements.

Key words: large language models (LLM), retrieval-augmented generation (RAG), knowledge graph (KG), electric power production safety, accident analysis, DeepSeek-R1

中图分类号:

X913.2安全信息论

晋良海, 张倩, 徐童欣, 陈云, 彭仲文. 融合LLM-RAG-KG的电力生产安全事故问答大模型^*[J]. 中国安全科学学报, 2026, 36(3): 66-73.

JIN Lianghai, ZHANG Qian, XU Tongxin, CHEN Yun, PENG Zhongwen. A large model for analyzing power production safety accidents integrating LLM, RAG and KG[J]. China Safety Science Journal, 2026, 36(3): 66-73.

图/表 4

图1

表1

DeepSeek-R1强化模型回答展示

问题

发电机大轴弯曲的原因是什么?

回答

根据提供的资料分析,发电机大轴弯曲的主要原因可归纳为以下技术和管理层面的关键因素:
1)直接技术原因:①高压转子胀差超限未及时处理:高压转子在运行中因热膨胀产生胀差(+5.02 mm),远超规程允许值(报警值+3.0 mm,停机值+4.0 mm)。未按规定在胀差达到+4.0 mm时立即停机,导致高压前/后汽封及隔板汽封发生轴向与径向碰磨。②设备监测失效:功率表因接线错误导致并网后无指示(有功/无功功率均无法显示),使汽轮机数字电液控制系统系统失去功率反馈控制:油动机被迫全开(推测负荷达33~45 MW),蒸汽流量异常升高至约220 t/h;高蒸汽流量加剧了高压转子的热膨胀速率。③机组参数匹配失控:启动至并网阶段主蒸汽温度持续偏高;锅炉多支油枪投入造成主蒸汽温度调节困难,为高压胀差的快速增加提供热力学条件
2)管理及操作失误:①违反运行规程:运行人员在高压胀差已达+4.46 mm时才解列停机(超出规程停机阈值11.5%);惰走时间长达24 min,延长了摩擦作用时间。②系统性风险管控缺失:仪表接线错误未被及时发现并纠正;高温工况下缺乏有效的参数协调控制措施
3)关联安全隐患:参考其他事故案例可得,氢气置换不彻底或压缩空气未排空虽未直接导致本次大轴弯曲事件,但反映出电厂在关键工艺过程控制中的系统性缺陷(如安全隔离措施执行不到位),此类管理漏洞可能间接影响设备可靠性
结论:发电机大轴弯曲的根本原因是热膨胀失控与保护机制失效的耦合作用:设备监测缺陷导致工况异常未被识别→高温与高流量加速胀差增长→规程执行滞后加剧机械损伤→最终引发大轴塑性变形。此事件暴露出从仪表维护到应急处置的全流程管理漏洞

表1

图2

图3

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融合LLM-RAG-KG的电力生产安全事故问答大模型^*

A large model for analyzing power production safety accidents integrating LLM, RAG and KG

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