基于大兴安岭季节性火灾风险动态调整地面临时扑救基地

doi:10.11707/j.1001-7488.LYKX20250229

摘要/Abstract

摘要：

目的: 基于燃烧概率模型揭示季节性森林火灾风险的空间分异规律，优化林火扑救资源配置，为改进森林扑火资源管理模式、提升森林火灾防控能力提供理论支持和实践指导。方法: 以我国重要林区大兴安岭为研究对象，采用改进的燃烧概率模型模拟春季、夏季、秋季3个火险期的燃烧概率时空分布。通过大量迭代模拟，量化不同季节的燃烧概率（BP）、火蔓延速率（ROS）和火强度（FI），并评估初始扑救成功率。模拟情景包括基准情景（当前的扑火资源配置）和优化情景（基于燃烧概率调整地面临时扑火基地）。基于每个季节的森林火灾风险，将临时扑火基地（或扑火点）从低BP区调整到高BP区。春季重点加强东部和南部落叶针叶林的资源配置，秋季加强混交林区域的资源配置。利用单因素重复方差分析比较季节间的BP、ROS、FI差异，并通过配对样本t检验验证调整前后的效果。评估指标包括响应时间、初始扑救成功率和燃烧概率。结果: 大兴安岭森林火灾风险存在显著的季节性差异。春季森林火灾的过火面积占全年的80%以上。春季的干燥可燃物条件（FFMC 85+）和高火天气指数会加剧火的蔓延，夏季和秋季的降水对火灾风险有显著抑制作用。BP模型结果显示，春季平均BP为0.002 6，有94.6%区域可能发生燃烧，ROS（6.3 m·min^?1）和FI（4 504.6 kW·m^?1）年内最高。夏季平均BP为0.000 9，比春季降低73.6%；ROS和FI分别降至2.6 m·min^?1和1 864.1 kW·m^?1。秋季只有20.3%的区域可能燃烧，平均BP为0.000 1，ROS和FI进一步降至2.4 m·min^?1和1 512.7 kW·m^?1。基于BP模拟结果动态调整地面临时扑火基地后，春季、夏季和秋季临时扑火点数量分别减少14.4%、27.1%和33.3%，响应时间仍满足<1.5 h要求，初始扑救成功率维持在77.2%~93.5%。优化调整地面临时扑火资源后，燃烧概率（P=0.84）和火行为（P=0.91）也未发生显著变化。结论: 本研究量化大兴安岭季节性森林火灾风险的空间分异规律，提出基于BP动态调整地面有限扑火资源，实现了减少14%~33%临时扑火基地并能维持当前扑救效率的目的。

关键词: 燃烧概率模型, 林火模拟, 林火管理, 火行为, 大兴安岭

Abstract:

Objective: Based on the burn probability model, this study aims to uncover the spatial patterns of seasonal forest fire risks, and optimize the allocation of forest fire suppression resources, so as to provide theoretical support and practical guidance for improving the firefighting resource management in northern forests and enhancing forest fire prevention and control capabilities. Method: The Daxing’anling Mountains, an important forest area in China, was targeted. An enhanced burn probability model was employed to simulate the spatiotemporal dynamics of burn probabilities across the three distinct fire-risk seasons: spring, summer, and autumn for Daxing’anling forest region. Extensive iterative simulations were used to quantify seasonal variations in burn probabilities (BP), fire spread rates (ROS), and fire intensities (FI), and thereby assess the initial attack success rate. Two simulation scenarios were developed for comparative analysis: a baseline scenario reflecting current firefighting resource allocations and an optimized scenario that adjusted the placement and amount of temporary ground firefighting bases according to BP distribution. Resource reallocation strategies were designed to relocate temporary firefighting bases from areas of low BP areas to high BP areas. The resource allocation was strengthened in deciduous coniferous forests in the eastern and southern regions during spring, and the resource allocation was strengthened in mixed forest zones in autumn. One-way repeated measures ANOVA was used to examine seasonal differences in BP, ROS, and FI, and paired-sample t-tests was used to validate the efficacy of pre- and post-adjustment outcomes. Key evaluation metrics encompassed response time, initial attack success rate, and burn probability, providing a comprehensive framework for assessing the impact of resource optimization on fire management effectiveness. Result: There were significant seasonal variations in forest fire risks in Daxing’anling region, with the burnt area in spring accounting for over 80% of the annual burnt area. The combination of dry fuel conditions (fine fuel moisture code, FFMC > 85) and elevated fire weather index (FWI) during spring significantly amplified fire spread, whereas precipitation in summer and autumn exerted a strong suppressive effect on fire risks. The model simulations revealed that the average BP in spring was 0.002 6, with 94.6% of the area exhibiting potential for combustion. During this period, the ROS peaked at 6.3 m·min^?1, and FI reached its highest annual value of 4 504.6 kW·m^?1. In contrast, summer showed a substantial decline in BP to an average of 0.000 9, which is 73.6% lower than that in spring, accompanied by decreases in ROS to 2.6 m·min^?1 and FI to 1864.1 kW·m^?1. Autumn experienced the lowest fire risk, with only 20.3% of the area at risk of burning, with an average BP of 0.000 1, and further reductions in ROS to 2.4 m·min^?1 and FI to 1 512.7 kW·m^?1. Following the dynamic reallocation of temporary ground firefighting bases informed by BP simulation outcomes, the number of temporary firefighting bases in spring, summer, and autumn was reduced by 14.4%, 27.1%, and 33.3%, respectively. Despite these reductions, the response times continued to meet the critical threshold of <1.5 hours, while the initial attack success rate was sustained within the range of 77.2%?93.5%. The optimization of temporary ground firefighting resource allocation resulted in no statistically significant changes in burn probability (P = 0.84) or fire behavior (P = 0.91), underscoring the efficacy of the adaptive management strategy. Conclusion: This study can quantify the spatial differentiation patterns of seasonal forest fire risks in Daxing’anling and proposes a dynamic adjustment approach for optimizing the allocation of limited ground firefighting resources based on the BP simulations. The approach has successfully achieved the dual objective of reducing the number of temporary firefighting bases by 14%?33% while maintaining established firefighting goals.

Key words: burn probability model, wildfire behavior simulation, wildfire management, fire behavior, Daxing’anling

中图分类号:

S762

宗学政,田晓瑞,崔文彬,舒立福,王明玉. 基于大兴安岭季节性火灾风险动态调整地面临时扑救基地[J]. 林业科学, 2026, 62(4): 154-163.

Xuezheng Zong,Xiaorui Tian,Wenbin Cui,Lifu Shu,Mingyu Wang. Dynamic Adjustment of Temporary Ground Firefighting Bases Based on Seasonal Fire Risk in Daxing’anling[J]. Scientia Silvae Sinicae, 2026, 62(4): 154-163.

图/表 6

图1

表1

BP模型的输入和燃烧参数"

变量 Variable	格式 Format	覆盖期间 Period covered	描述 Description
可燃物类型 Fuel types	栅格Raster（.asc）	2020	可燃物类型包括5类：O-1a（草地）、C-5（常绿针叶林）、M-1a（落叶针叶林）、D-1 （阔叶林）和M-1b（混交林） Including five categories: O-1a (grassland), C-5 (evergreen coniferous forest), M-1a (deciduous coniferous forest), D-1 (broadleaf forest), and M-1b (mixed forest)（Hirsch，1996）
数字高程模型 DEM	栅格Raster（.asc）	—	研究区地形 Topography of the study area
火发生密度Fire occurrence density	栅格Raster（.asc）	2000—2020	基于历史记录（3个季节的人为火和雷击火）生成6个火发生密度图 Six fire occurrence density maps generated based on historical records (including both human-caused and lightning-caused fires across three seasons)
响应时间 Response time	栅格Raster（.asc）	2020	由扑火基地从地面或空中到达火场所需的最快时间 The minimum time required for firefighting teams to reach the fire site from ground or aerial bases（Tian et al., 2020）
季节 Season	字符Character	—	根据物候和火活动将火险期划分为3个季节：春季（3—5月）、夏季（6—8月）和秋季（9—10月） The fire risk period is divided into three seasons based on phenology and fire activity: Spring (March–May), Summer (June–August), and Autumn (September–October)
点燃概率 Ignition probability	文件File（.csv）	2000—2020	根据历史记录采用指数函数生成各季节雷击点燃概率、各季节人为点燃概率、日雷击火概率和人为火概率 Seasonal lightning ignition probability and human-caused ignition probability, and daily lightning fire probability and human-caused fire probability generated using an exponential function based on historical records
火天气列表 Fire weather list	文件File（.csv）	2000—2020	使用R Studio的‘cffdrs’包根据观测天气数据计算 Calculated from observed weather data using the 'cffdrs' package in R Studio（Wang et al., 2017）

表1

图2

图3

图4

图5

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