基于系统动力学的装配式建筑项目进度分析与系统实现

doi:10.3785/j.issn.1008-973X.2025.06.017

浙江大学学报(工学版)

2025, Vol. 59

Issue (6): 1265-1276 DOI: 10.3785/j.issn.1008-973X.2025.06.017

土木工程、交通工程

基于系统动力学的装配式建筑项目进度分析与系统实现

李昊翔(

),侯公羽*(

),陈钦煌,王丹丹,邵耀华,陶志刚

中国矿业大学（北京）力学与土木工程学院，北京 100083

Analysis and system implementation for prefabricated construction project schedule based on system dynamics

Haoxiang LI(

),Gongyu HOU*(

),Qinhuang CHEN,Dandan WANG,Yaohua SHAO,Zhigang TAO

School of Mechanics and Civil Engineering, China University of Mining and Technology-Beijing, Beijing 100083, China

全文: PDF(2467 KB) HTML

摘要：

为了便于装配式建筑项目的进度分析与管理，提出基于系统动力学的进度分析方法. 根据装配式建造的特点，改进装配式建筑项目的双代号网络计划，并引入基于结构矩阵求解双代号网络计划的改进算法(SM-A1). 通过确定系统变量、构建因果关系回路图和混合图、确定变量间的数学关系等过程，建立适用于装配式建筑项目的单项作业进度模拟系统动力学模型(S-SD)，并验证S-SD的有效性与可靠性. 将SM-A1与S-SD相结合，构建装配式建筑项目进度分析系统(PCPSAS)框架，设计系统的数据格式、核心模块及界面，生成可执行程序，并通过实例验证PCPSAS的有效性. 结果表明，PCPSAS可快速准确地计算装配式建筑项目的双代号网络计划的时间参数和识别关键工作，且能有效地分析不同纠偏策略对项目进度和成本的影响.

关键词： 装配式建筑项目; 结构矩阵; 双代号网络; 系统动力学; 纠偏策略

Abstract:

A project schedule analysis method based on the system dynamics was proposed to facilitate the analysis and management of the prefabricated construction project schedule. The activity-on-arc network planning for prefabricated construction projects was improved according to the characteristics of prefabricated construction, and an improved algorithm for solving the activity-on-arc network planning based on the structure matrix (SM-A1) was introduced. By determining the system variables, constructing the causal loop diagram and the mixed graphs, and defining the mathematical relationships between variables, a system dynamics model for simulating the schedule of a single task (S-SD) in prefabricated construction projects was established, and its validity and reliability were verified. Combining SM-A1 and S-SD, a framework for the prefabricated construction project schedule analysis system (PCPSAS) was developed, including the design of the system’s data format, core modules, and interface, as well as the generation of an executable program. The PCPSAS was validated through the case study. The experimental results demonstrate that the PCPSAS can quickly and accurately calculate the activity-on-arc network planning time parameters for the prefabricated construction project, identify the critical tasks, and effectively analyze the impact of different corrective strategies on the prefabricated construction project schedule and cost.

Key words: prefabricated construction project structure matrix activity-on-arc network system dynamics corrective strategy

收稿日期: 2024-06-03 出版日期: 2025-05-30

CLC:

TU 712

基金资助: 深部岩土力学与地下工程国家重点实验室创新基金资助项目(SKLGDUEK202201).

通讯作者: 侯公羽 E-mail: hoxiangli@163.com;hgyht@126.com

作者简介: 李昊翔（1990—），男，博士生，从事工程管理研究. orcid.org/0000-0002-8838-8227. E-mail：hoxiangli@163.com

	服务
	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	作者相关文章
	李昊翔
	侯公羽
	陈钦煌
	王丹丹
	邵耀华
	陶志刚

引用本文:

李昊翔,侯公羽,陈钦煌,王丹丹,邵耀华,陶志刚. 基于系统动力学的装配式建筑项目进度分析与系统实现[J]. 浙江大学学报(工学版), 2025, 59(6): 1265-1276.

Haoxiang LI,Gongyu HOU,Qinhuang CHEN,Dandan WANG,Yaohua SHAO,Zhigang TAO. Analysis and system implementation for prefabricated construction project schedule based on system dynamics. Journal of ZheJiang University (Engineering Science), 2025, 59(6): 1265-1276.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2025.06.017 或 https://www.zjujournals.com/eng/CN/Y2025/V59/I6/1265

图 1 装配式建筑项目的双代号网络图

表 1 搭接关系转化规则

表 2 影响装配式建筑项目进度的主要因素

表 3 系统中主要变量的类型

图 2 因果关系回路图

图 3 生产子系统的混合图

图 4 纠偏子系统的混合图

图 5 不返工事件正态分布图

图 6 加班对生产效率的影响

表 4 作业温度与生产效率降低的对照表

图 7 S-SD极端条件检验

图 8 S-SD的积分误差测试图

图 9 线管安装实际工日需求与S-SD模拟需求的对比

图 10 PCPSAS的系统结构图

图 11 PCPSAS中S-SD模块的界面

表 5 深圳市某装配式建筑项目概况

表 6 工厂内作业的工作信息

图 12 案例工厂内作业的双代号网络计划

图 13 搭接关系转化后的现场的双代号网络计划

图 14 SM-A1模块的计算结果截图

表 7 SM-A1模块的计算结果

表 8 S-SD模块的主要参数设定

表 9 S-SD模块对不同策略下的工厂内工作D的进度模拟结果

1	连静. 装配式施工项目调度多目标优化研究 [D]. 西安: 西安建筑科技大学, 2020. LIAN Jing. Research on multi-objective optimization of prefabricated construction project scheduling [D]. Xi’an: Xi’an University of Architecture and Technology, 2020.
2	CHO K, AHN S, PARK K, et al Schedule delay leading indicators in precast concrete construction projects: qualitative comparative analysis of Korean cases[J]. Journal of Management in Engineering, 2021, 37 (4): 04021024
3	ARASHPOUR M, WAKEFIELD R, LEE E W M, et al Analysis of interacting uncertainties in on-site and off-site activities: implications for hybrid construction[J]. International Journal of Project Management, 2016, 34 (7): 1393- 1402
4	JI Y, QI L, LIU Y, et al Assessing and prioritising delay factors of prefabricated concrete building projects in China[J]. Applied Sciences, 2018, 8 (11): 2324
5	沈楷程. 装配式建造过程返工风险研究[D]. 北京: 清华大学, 2020. SHEN Kaicheng. Research on rework risk of prefabricated construction process [D]. Beijing: Tsinghua University, 2020.
6	WASANA K H I, GUNATILAKE S, FASNA M F F. Performance comparison of prefabricated building construction projects vs. traditional on-site construction projects [C]// Proceedings of the Moratuwa Engineering Research Conference. Moratuwa: IEEE, 2019: 169–174.
7	李丽红, 于明瑜, 辛雨泽基于EFA-CFA的装配式建筑工程项目返工成因实证研究[J]. 项目管理评论, 2021, (2): 42- 47 LI Lihong, YU Mingyu, XIN Yuze Empirical study on the causes of rework in prefabricated building projects based on EFA-CFA[J]. Project Management Review, 2021, (2): 42- 47
8	崔佳林. 基于系统动力学的装配式建筑施工进度风险管理研究 [D]. 北京: 北方工业大学, 2021. CUI Jialin. Research on construction schedule risk management of prefabricated project based on system dynamics [D]. Beijing: North China University of Technology, 2021.
9	LI C Z, XU X, SHEN G Q, et al A model for simulating schedule risks in prefabrication housing production: a case study of six-day cycle assembly activities in Hong Kong[J]. Journal of Cleaner Production, 2018, 185: 366- 381
10	张延涛, 苑晨丹双代号搭接网络向VCPM网络转化模型研究[J]. 内蒙古大学学报: 自然科学版, 2018, 49 (1): 90- 95 ZHANG Yantao, YUAN Chendan Research on the model for transforming AOA spliced networks into VCPM networks[J]. Journal of Inner Mongolia University: Natural Science Edition, 2018, 49 (1): 90- 95
11	李昊翔, 侯公羽, 陈钦煌, 等基于结构矩阵求解双代号网络计划的改进算法[J]. 华中科技大学学报: 自然科学版, 2024, 52 (11): 147- 152 LI Haoxiang, HOU Gongyu, CHEN Qinhuang, et al Improved algorithm for solving activity-on-arc network planning based on structure matrix[J]. Journal of Huazhong University of Science and Technology: Natural Science Edition, 2024, 52 (11): 147- 152
12	佟鹤晶, 乞建勋搭接网络向双代号网络的转化[J]. 技术经济, 2009, 28 (10): 125- 128 TONG Hejing, QI Jianxun Transforming spliced network to AoA network[J]. Journal of Technology Economics, 2009, 28 (10): 125- 128 doi: 10.3969/j.issn.1002-980X.2009.10.025
13	WANG T, FORD D, CHONG H, et al. Causes of delays in the construction phase of Chinese building projects [J], Engineering, Construction and Architectural Management, 2018, 25(11): 1534–1551.
14	YAP J B H, GOAY P L, WOON Y B, et al Revisiting critical delay factors for construction: analysing projects in Malaysia[J]. Alexandria Engineering Journal, 2021, 60 (1): 1717- 1729
15	MAHAMID I Study of relationship between rework and labor productivity in Building[J]. Revista de la Construccion, 2020, 19 (1): 30- 40
16	KAZAZ A, ULUBEYLI S, TUNCBILEKLI N Causes of delays in construction projects in Turkey[J]. Journal of Civil Engineering and Management, 2012, 18 (3): 426- 435
17	ALSULIMAN J A Causes of delay in Saudi public construction projects[J]. Alexandria Engineering Journal, 2019, 58 (2): 801- 808 doi: 10.1016/j.aej.2019.07.002
18	VILES E, RUDELI N C, SANTILLI A Causes of delay in construction projects: a quantitative analysis[J]. Engineering, Construction and Architectural Management, 2020, 27 (4): 917- 935
19	HWANG B G, LEONG L P Comparison of schedule delay and causal factors between traditional and green construction projects[J]. Technological and Economic Development of Economy, 2013, 19 (2): 310- 330
20	ZHAO Y, CHEN W, YANG Z, et al Analysis on risk factors related delay in PCPs[J]. Engineering, Construction and Architectural Management, 2023, 30 (10): 4609- 4644
21	HAN S, LOVE P, PEÑA-MORA F A system dynamics model for assessing the impacts of design errors in construction projects[J]. Mathematical and Computer Modelling, 2013, 57 (9/10): 2044- 2053
22	JARKAS A M, BITAR C G Factors affecting construction labor productivity in Kuwait[J]. Journal of Construction Engineering and Management, 2012, 138 (7): 811- 820
23	LI C Z, HONG J, FAN C, et al Schedule delay analysis of prefabricated housing production: a hybrid dynamic approach[J]. Journal of Cleaner Production, 2018, 195: 1533- 1545
24	KIM H, SOIBELMAN L, GROBLER F Factor selection for delay analysis using knowledge discovery in databases[J]. Automation in Construction, 2008, 17 (5): 550- 560
25	ZHAO Y, CHEN W, ARASHPOUR M, et al. Predicting delays in prefabricated projects: SD-BP neural network to define effects of risk disruption [J]. Engineering, Construction and Architectural Management, 2022, 29(4): 1753–1776.
26	NASIRZADEH F, NOJEDEHI P Dynamic modeling of labor productivity in construction projects[J]. International Journal of Project Management, 2013, 31 (6): 903- 911
27	KAMING P F, HOLT G D, KOMETA S T, et al Severity diagnosis of productivity problems: a reliability analysis[J]. International Journal of Project Management, 1998, 16 (2): 107- 113
28	WOO S Simulation analysis of labor performance during overtime and impact on project duration[J]. KSCE Journal of Civil Engineering, 2016, 20 (7): 2614- 2623
29	CHANG C K, WOO S Critical review of previous studies on labor productivity loss due to overtime[J]. KSCE Journal of Civil Engineering, 2017, 21 (7): 2551- 2557 doi: 10.1007/s12205-017-1652-0
30	ZHANG P, DESCHENES O, MENG K, et al Temperature effects on productivity and factor reallocation: evidence from a half million Chinese manufacturing plants[J]. Journal of Environmental Economics and Management, 2018, 88: 1- 17 doi: 10.1016/j.jeem.2017.11.001
31	CAI X, LU Y, WANG J The impact of temperature on manufacturing worker productivity: evidence from personnel data[J]. Journal of Comparative Economics, 2018, 46 (4): 889- 905 doi: 10.1016/j.jce.2018.06.003
32	SOMANATHAN E, SOMANATHAN R, SUDARSHAN A, et al The impact of temperature on productivity and labor supply: evidence from Indian manufacturing[J]. Journal of Political Economy, 2021, 129 (6): 1797- 1827 doi: 10.1086/713733
33	徐淑玲. 工作效率时变的调度与优化问题研究 [D]. 合肥: 合肥工业大学, 2021. XU Shuling. Research on scheduling and optimization problems of real-time changes in work efficiency [D]. Hefei: Hefei University of Technology, 2021.
34	VANHOUCKE M, COELHO J A tool to test and validate algorithms for the resource-constrained project scheduling problem[J]. Computers and Industrial Engineering, 2018, 118: 251- 265 doi: 10.1016/j.cie.2018.02.001

[1]	楼齐峰, 马晓龙, 叶盈, 梅振宇. 基于出行成本的停车收费和供给政策影响分析[J]. 浙江大学学报(工学版), 2016, 50(2): 257-264.
[2]	姜飞龙,陶国良,刘昊,赵勇,李庆伟. 基于气动肌肉仿人下肢动力学[J]. 浙江大学学报(工学版), 2015, 49(11): 2054-2062.
[3]	韩海荣, 张树有, 裘乐淼. 基于动态设计结构矩阵的客户需求反馈导航技术[J]. J4, 2011, 45(4): 637-643.
[4]	占甫关富玲. 含三维间隙铰空间可展机构动力学数值分析[J]. J4, 2009, 43(1): 177-182.
[5]	郭磊郝志勇林琼. 柴油机曲轴与气缸体系统动力学仿真研究[J]. J4, 2007, 41(5): 780-784.
[6]	郭峰武建伟潘双夏冯培恩常艳. 基于设计结构矩阵族的过程建模方法研究[J]. J4, 2006, 40(9): 1609-1613.

Viewed

Full text

Abstract

Cited

Shared

Discussed