Research on construction and application of an intelligent risk management model for urban building collapse

doi:10.16265/j.cnki.issn1003-3033.2025.S2.0025

Abstract

Abstract:

To enhance the intrinsic safety level of urban buildings, a smart control and management model for urban building collapse risks was proposed, which consists of ″wide-scale census + refined monitoring + professional team verification″. Firstly, InSAR technology was employed for a wide-scale census of urban buildings. Secondly, intelligent sensing devices were utilized for refined monitoring. Then, on-site professional verification was conducted. Finally, empirical research was carried out by taking Shenzhen City and a single building as examples. Based on the intelligent management and control governance model that involves extensive scanning, meticulous monitoring, and specialized verification, it is possible to effectively identify urban buildings that may pose risks. Further, displacement monitoring equipment could be installed. According to the warning thresholds such as inclination, cracks, subsidence, strain, and displacement, regular monitoring could be conducted on the risk buildings that require local attention and priority focus. Then, targeted verification, assessment, and the adoption of necessary control measures could be carried out, effectively ensuring the safety of urban buildings.

Key words: urban building collapse, interferometric synthetic aperture radar(InSAR), large-scale survey, fine-scale monitoring, professional verification

CLC Number:

X913.4安全系统工程

LI Xiteng, MA Haitao, YU Zhengxing, ZHOU Yanfeng, LI Xikun. Research on construction and application of an intelligent risk management model for urban building collapse[J]. China Safety Science Journal, 2025, 35(S2): 189-195.

Figures/Tables 7

Fig.1

Table 1

Table 2

Table 3

Table 4

Table 5

Table 6

References 21

[1]	湖南省应急管理厅. 湖南长沙“4·29”特别重大居民自建房倒塌事故调查报告公布[EB/OL].[2023-05-21]. https://yjt.hunan.gov.cn/yjt/xxgk/gzdt/ajyw/202305/t20230521_29344778.html.
[2]	浙江省应急管理厅. 29人死亡,41名公职人员被处理,山西聚仙饭店坍塌事故调查报告公布[EB/OL].[2021-08-19]. https://yjt.zj.gov.cn/art/2021/8/19/art_1228978417_59065106.html.
[3]	中华人民共和国应急管理部. 湖南长沙"4·29"特别重大居民自建房倒塌事故调查报告[EB/OL].[2024-2-29]. https://www.mem.gov.cn/gk/sgcc/tbzdsgdcbg/2023dcbg_5532/202305/W020240229381934853466.pdf.
[4]	黄委彬, 杨梦诗, 赵志芳, 等. 星载InSAR数据驱动的城市建筑稳定性评估:以昆明市为例[J]. 武汉大学学报:信息科学版, 2025, 50(8): 1 669-1 681.
	HUANG Weibin, YANG Mengshi, ZHAO Zhifang, et al. Satellite-based InSAR data-driven urban building stability assessment:a case study of kunming city[J]. Geomatics and Information Science of Wuhan University, 2025, 50(8): 1 669-1 681.
[5]	周云, 陈建炜, 邹少豪, 等. 基于星载InSAR技术的城市建筑群变形监测与安全风险评估研究综述[J/OL]. 土木工程学报,1-25.[2024-11-22].https://doi.org/10.15951/j.tmgcxb.24080654.
	ZHOU Yun, CHEN Jianwei, ZOU Shaohao, et al. A review of urban building complex deformation monitoring and safety risk assessment based on spaceborne InSAR technology[J/OL]. China Civil Engineering Journal,1-25.[2024-11-22].https://doi.org/10.15951/j.tmgcxb.24080654.
[6]	杨磊, 罗惠恒, 姜鹏, 等. 利用时序InSAR技术的大型水电站库岸滑坡监测与应用[J]. 地理空间信息, 2025, 23(6):13-17.
	YANG Lei, LUO Huiheng, JIANG Peng, et al. Monitoring and application of large hydropower station bank landslide based on time-series InSAR technology[J]. Geospatial Information, 2025, 23(6):13-17.
[7]	刘世伟, 刘洪亮, 邓选滔, 等. 基于星载时序InSAR的长距离输水管线健康监测[J]. 地理空间信息, 2025, 23(6):27-31,36.
	LIU Shiwei, LIU Hongliang, DENG Xuantao, et al. Long Distance water transmission pipeline health monitoring based on satellite-borne time-series InSAR[J]. Geospatial Information, 2025, 23(6):27-31,36.
[8]	胡晓宁, 宋闯, 余琛, 等. 基于时序InSAR技术的长白山天池火山长周期形变监测与分析[J]. 地球物理学报, 2025, 68(5): 1 660-1 677.
	HU Xiaoning, SONG Chuang, YU Chen, et al. Long-term deformation monitoring and analysis of Changbaishan Tianchi volcano based on time-series InSAR technique[J]. Chinese Journal of Geophysics, 2025, 68(5): 1 660-1 677.
[9]	杨洋, 贾洪果, 柏铮航, 等. 联合机器学习与SBAS-InSAR的青藏高原冻土形变监测[J]. 测绘通报, 2025(4):45-50. doi: 10.13474/j.cnki.11-2246.2025.0408
	YANG Yang, JIA Hongguo, BO Zhenghang, et al. Integrated monitoring of permafrost deformation in the Qinghai-Xizang plateau using machine learning and SBAS-InSAR[J]. Bulletin of Surveying and Mapping, 2025(4):45-50. doi: 10.13474/j.cnki.11-2246.2025.0408
[10]	李笑林, 杨璐, 许镇, 等. 建筑结构安全智能化监测研究现状及展望[J]. 土木工程与管理学报, 2021, 38(5):152-164.
	LI Xiaolin, YANG Lu, XU Zhen, et al. Research status and prospect of intelligent monitoring of structure safety[J]. Journal of Civil Engineering and Management, 2021, 38(5):152-164.
[11]	蒋维乐, 姚坤, 林启敬, 等. 结构健康监测系统在木结构古建筑中的应用[J]. 传感技术学报, 2024, 37(8): 1 295-1 306.
	JIANG Weile, YAO Kun, LIN Qijing, et al. Application of structural health monitoring system in wooden-structure ancient buildings[J]. Chinese Journal of Sensors and Actuators, 2024, 37(8): 1 295-1 306.
[12]	肖儒雅, 王迅, 孙静怡, 等. 国产SAR卫星差分干涉测量地表形变监测比较[J]. 武汉大学学报:信息科学版, 2025, 50(8): 1 517-1 526.
	XIAO Ruya, WANG Xun, SUN Jingyi, et al. Comparisons of differential interferometry of Chinese SAR satellites in ground deformation monitoring[J]. Geomatics and Information Science of Wuhan University, 2025, 50(8): 1 517-1 526.
[13]	胡文. PS-InSAR技术在城市地表沉降监测的应用探索[C]. 2019年12月建筑科技与管理学术交流会论文集, 2019:99-104.
[14]	于忠海, 闫立波, 刘茜, 等. 基于陆探一号SAR卫星的地质灾害普查监测技术研究及应用[J]. 测绘通报, 2024(11):97-101,176. doi: 10.13474/j.cnki.11-2246.2024.1117
	YU Zhonghai, YAN Libo, LIU Xi, et al. Research and application of Lutan-1 SAR satellite in survey and monitoring of catastrophic geohazards[J]. Bulletin of Surveying and Mapping, 2024(11):97-101,176. doi: 10.13474/j.cnki.11-2246.2024.1117
[15]	董鹏. 基于InSAR的建筑施工安全风险监测探讨[J]. 城市建设理论研究:电子版, 2025(10):88-90.
[16]	赵奇. 基于GNSS和InSAR技术的矿区建筑物形变监测[J]. 测绘通报, 2024(11):126-132,166. doi: 10.13474/j.cnki.11-2246.2024.1122
	ZHAO Qi. Monitoring of deformation in mining buildings based on GNSS and InSAR technologies[J]. Bulletin of Surveying and Mapping, 2024(11):126-132,166. doi: 10.13474/j.cnki.11-2246.2024.1122
[17]	李桠楠. 基于InSAR技术的城市建筑地震灾害风险评估[D]. 北京: 中国地震局地震预测研究所, 2024.
	LI Ya'nan. Urban building seismic hazard risk assessment based on InSAR technology[D]. Beijing: The Institute of Earthquake Forecasting, 2024.
[18]	刘新宇, 王勇, 唐超. 静力水准自动化测量技术应用于地铁隧道结构监测[J]. 测绘通报, 2021(8):69-73. doi: 10.13474/j.cnki.11-2246.2021.0243
	LIU Xinyu, WANG Yong, TANG Chao. Application of static leveling automatic measurement technology in subway tunnel structure monitoring[J]. Bulletin of Surveying and Mapping, 2021(8):69-73. doi: 10.13474/j.cnki.11-2246.2021.0243
[19]	周云, 邹少豪, 周晓枫, 等. 基于星载InSAR技术进行房屋建筑安全风险评估的指标体系综述[J/OL]. 建筑结构学报,1-28.[2025-10-10].https://doi.org/10.14006/j.jzjgxb.2025.0158.
	ZHOU Yun, ZOU Shaohao, ZHOU Xiaofeng, et al. A review of indicator systems for building safety risks assessment using spaceborne InSAR technology[J/OL]. Journal of Building Structures,1-28.[2025-10-10].https://doi.org/10.14006/j.jzjgxb.2025.0158.
[20]	詹学丽, 王岩飞, 王超, 等. 一种基于脉冲压缩的机载条带SAR重叠子孔径实时成像算法[J]. 雷达学报, 2015, 4(2):199-208.
	ZHAN Xueli, WANG Yanfei, WANG Chao, et al. Research on overlapped subaperture real-time imaing algorithm for pulse compression airborne strip SAR system[J]. Journal of Radars, 2015, 4(2):199-208.
[21]	陈鑫, 童啄时, 刁鑫鹏, 等. 地铁沿线地表形变MT-InSAR精细化监测与预测[J]. 测绘科学, 2025, 50(4):38-49.
	CHEN Xin, TONG Zhuoshi, DIAO Xinpeng, et al. Fine monitoring and prediction of surface deformation along subway lines using MT-InSAR[J]. Science of Surveying and Mapping, 2025, 50(4):38-49.

参数	计算方法
d_3y	选取3年累计沉降最大的聚类点, 计算其3年累计沉降值
V_1y	选取3年累计沉降最大的聚类点, 计算其近1年的沉降速率值
T_3y	计算聚类点对的3年累计倾斜值TAB,选取其最大值。当选用分辨率为3 m的X波段数据时, 聚类点水平距离宜不小于10 m
M_1y	根据确定T_3y的聚类点对,计算其近一年的倾斜速率

等级	d_3y /mm	V_1y/(mm·a^-1)	T_3y	M_1y/a
Ⅰ	<18	<12	<1‰	<0.8‰
Ⅱ	18~24	12~24	1‰~1.5‰	0.8‰~1‰
Ⅲ	24~48	24~32	1.5‰~3‰	1‰~2‰
Ⅳ	>48	>32	>3‰	>2‰

传感器	倾斜/ (mm·m^-1)	裂缝/ mm	应变/ με	沉降/ mm
合格	≤±0.5	≤±0.3	≤±50	≤±2
不合格/失效	>±0.5	>±0.3	>±50	>±2

阈值	倾斜/ (mm·m^-1)	裂缝/ mm	沉降/ mm	应变/ με	位移/ mm
红	2	1	20	400	2
橙	1.5	0.75	15	300	1.5
黄	1	0.5	10	200	1
蓝	0.5	0.25	5	100	0.5

序号	区名称	重点关注建筑数量/栋	占比/%
1	宝安区	450	3.64
2	南山区	300	4.96
3	光明区	2	0.20
4	龙华区	70	1.08
5	福田区	66	1.64
6	龙岗区	98	0.40
7	罗湖区	18	0.47
8	盐田区	0	0.00
9	坪山区	16	0.23
10	大鹏新区	2	0.44