Evaluation of Airport Rigid Pavement Grades and 
Parameter Sensitivity

doi:10.3969/j.issn.1674-0696.2026.02.03

Abstract

Abstract: The development trend towards larger aircraft and more complex load spectra directly links the evaluation accuracy of the load-bearing capacity of airport rigid pavements to flight safety and runway service life. The traditional CAN-PCN method exhibits limitations in aspects such as characterizing the time-varying effects of dynamic loads, nonlinear cumulative damage and the interlayer response of composite pavements. In response, the International Civil Aviation Organization (ICAO) has promulgated the ACR-PCR method based on the fatigue damage mechanism. Through empirical analysis, the key factors influencing the pavement classification rating (PCR) RPC and their mechanisms of action were systematically investigated. Based on layered elastic analysis (LEA) model and the cumulative damage factor (CDF) model, the parametric sensitivity analysis and case validation were conducted on a 4C-grade airport pavement by combining with CAAC-PCR software. The research results indicate that the surface layer thickness and flexural strength exert the most significant influence on RPC. A 10% increase in thickness elevates the RPC by 8%~12%, while an increase in flexural strength from 4.5 MPa to 6.0 MPa results in a remarkable RPC increase of 53%. A critical threshold exists for the reaction modulus of the subgrade top surface, beyond which RPC tends to stabilize. Under the action of the mixed aircraft fleet loading, the contribution rate of wide-bodied aircraft to the critical damage area of the runway surface is as high as 76.8%. This research provides a quantitative basis for the accurate evaluation of the load-bearing capacity of rigid airport pavements, thereby enhancing the scientific nature and engineering applicability of the assessment method.

Key words: highway engineering; airport pavement engineering; ACR-PCR method; stratified elasticity analysis; cumulative damage factor; parameter sensitivity

摘要： 航空器大型化与荷载谱复杂化的发展趋势，使得机场刚性道面承载能力的评价精度直接关系到飞行安全与跑道使用寿命。传统ACN-PCN方法在动态荷载时变效应表征、非线性累积损伤及复合道面层间响应等方面存在局限。鉴于此，国际民航组织颁布了基于疲劳损伤机理的ACR-PCR方法。通过实证分析，系统探讨了道面等级RPC(PCR)的关键影响因素及其作用机制。研究基于分层弹性理论(LEA)与累积损伤因子(CDF)模型，结合CAAC-PCR软件对某4C级机场道面进行参数敏感性分析与案例验证。研究结果表明：① 面层厚度与弯拉强度对RPC影响最为显著，厚度增加10%可使RPC提升8%~12%，弯拉强度从4.5 MPa增至6.0 MPa时，RPC增幅达53%；② 道基顶面反应模量存在临界阈值，超过该值后RPC趋于稳定；③ 在混合机群荷载作用下，宽体机型对道面临界损伤区域的贡献率高达76.8%。该研究为机场刚性道面承载能力的精准评价提供了量化依据，提升了评估方法的科学性与工程适用性。

关键词: 道路工程；机场铺面工程；ACR-PCR方法；分层弹性分析；累积损伤因子；参数敏感性

CLC Number:

U8
V351.11

LI Longhai, WU Siming. Evaluation of Airport Rigid Pavement Grades and Parameter Sensitivity[J]. Journal of Chongqing Jiaotong University(Natural Science), 2026, 45(2): 14-23.

李龙海，伍思铭. 机场刚性道面等级评价与参数敏感性分析[J]. 重庆交通大学学报（自然科学版）, 2026, 45(2): 14-23.

References

［1］中国民用航空局. 民用机场道面评价管理技术规范: MH/T 5024—2019［S］. 北京: 中国民航出版社, 2019.
CAAC. Specification for Pavement Evaluation and Management of Civil Airports: MH/T 5024—2019［S］.Beijing: China Civil Aviation Publishing House, 2019.
［2］ LOIZOS A, CHARONITIS G, KATSOULAS P. Rating the aircraft load and reporting the bearing capacity of rigid airport pavements［J］.Road Materials and Pavement Design, 2006, 7(3): 349-367.
［3］李乐, 岑国平, 季凯. 基于可靠度的机场刚性道面剩余寿命预测方法［J］. 四川建筑科学研究, 2009, 35(4): 98-101.
LI Le, CEN Guoping, JI Kai.On prediction method of airfield rigid pavement based on reliability［J］. Sichuan Building Science, 2009, 35(4): 98-101.
［4］张建霖, 郑小平. 机场道面的地基反应模量及承载力分析［J］. 土木工程学报, 2005, 38(5): 72-76.
ZHANG Jianlin, ZHENG Xiaoping. Analysis of response modulus and load-bearing capacity of the foundation for airport pavement［J］. China Civil Engineering Journal, 2005, 38(5): 72-76.
［5］万希存. 机场道面承载能力的评定方法与提高途径［J］. 民航经济与技术, 1997(8): 21-23.
WAN Xicun. Evaluation method and improvement way of airport pavement bearing capacity［J］. Civil Aviation Economics & Technology, 1997(8): 21-23.
［6］李萌, 谭悦. 基于机场刚性道面PCN评价方法研究［M］//上海空港: 第14辑. 上海: 上海世纪出版股份有限公司科学技术出版社, 2012: 65-69.
LI Meng, TAN Yue.Research on PCN evaluation method for airport rigid pavements［M］// Shanghai Airports: No. 14. Shanghai: Shanghai Century Publishing Co., Ltd., Science and Technology Press, 2012: 65-69.
［7］史超. 考虑交通量因素的道面 PCN 值的计算方法［J］. 机场建设, 2012(1): 26-29.
SHI Chao. Calculation method of PCN value of road surface considering traffic volume ［J］. Airport Construction, 2012(1): 26-29.
［8］张献民, 陈新春, 董倩, 等. 基于位移等效的复合道面PCN计算方法［J］．南京航空航天大学学报, 2015, 47(4): 532-538.
ZHANG Xianmin, CHEN Xinchun, DONG Qian, et al. PCN calculation method for composite pavement based on equivalent displacement ［J］. Journal of Nanjing University of Aeronautics & Astronautics, 2015, 47(4): 532-538.
［9］刘桂松, 翁兴中. 机场刚性道面PCN的参数取值与计算［C］// 第四届国际道路和机场路面技术大会论文集. 北京: 人民交通出版社, 2002: 577-579.
LIU Guisong, WENG Xingzhong. Parameter values and calculation of PCN for airport rigid pavement［C］// Proceedings of the Fourth International Conference on Road and Airport Pavement Technology. Beijing: China Communications Press, 2002: 577-579.
［10］王龙. 基于损伤等效的刚性道面PCN计算方法［D］. 上海: 同济大学, 2014.
WANG Long. PCN Calculation Method for Rigid Roadway Surface Based on Damage Equivalence ［D］. Shanghai: Tongji University, 2014.
［11］王龙. 机场刚性道面PCN计算方法的对比分析研究［J］. 西部交通科技, 2013(12): 67-71.
WANG Long. Comparative analysis studies on PCN calculation method of rigid air-port pavements［J］. Western China Communications Science & Technology, 2013(12): 67-71.
［12］李耘宇, 徐帆, 王永生 ,等. 基于频率谱和温度谱的纤维沥青混合料动态回弹模量研究［J］. 重庆交通大学学报(自然科学版), 2025, 44(10): 1-9.
LI Yunyu, XU Fan, WANG Yongsheng,et al. Dynamic resilient modulus of fiber asphalt mixture based on frequency spectrum and temperature spectrum［J］. Journal of Chongqing Jiaotong University(Natural Science), 2025, 44(10): 1-9.
［13］秦旻，窦丽红，许滌平，等. 基于数字图像处理的沥青路面均匀性评价综述［J］. 重庆交通大学学报（自然科学版）, 2025, 44(6): 1-14.
QIN Min，DOU Lihong，XU Diping，et al. A review of asphalt pavement uniformity evaluation based on digital image processing［J］. Journal of Chongqing Jiaotong University(Natural Science), 2025, 44(6): 1-14.
［14］张争奇，张英楠，黄硕磊. SBS-PU复合改性沥青及其混合料路用性能研究［J］. 重庆交通大学学报（自然科学版）, 2020, 39(5): 76-84.
ZHANG Zhengqi, ZHANG Yingnan, HUANG Shuolei. Road performance of SBS-PU composite modified asphalt and its mixture［J］. Journal of Chongqing Jiaotong University(Natural Science), 2020, 39(5): 76-84.
［15］ ARMENI A, LOIZOS A. Preliminary evaluation of the ACR-PCR system for reporting the bearing capacity of flexible airfield pavements［J］. Transportation Engineering, 2022, 8: 100117.
［16］ SUN Junyu, OH E, CHAI G, et al. Comparison between CAN-PCN and ACR-PCR for rigid airport pavement with case study［J］. Road Materials and Pavement Design, 2025, 26(3): 720-732.
［17］ ZHANG Yupeng, SUN Junyu, YANG Zeping, et al. Assessment of ACR-PCR for rigid airport pavements: Comparison with ACN-PCN system［J］. Geotechnical Research, 2025, 12(3): 117-127.
［18］ ICAO. Aerodome Design Manual, Part 3, Pavements ［M］. 2nd ed. Montreal: International Civil Aviation Organization, 1983: 1-3.
［19］ MICHEAL J. Standardized Method of Reporting Airport Pavement Strength-PCR: AC 150/5335-5C［R］. U.S.: Federal Aviation Administration, 2014: 3-10.
［20］孙倩. 机场水泥混凝土道面的累积损伤研究方法［J］. 工程技术研究, 2021, 6(3): 15-16.
SUN Qian. Research method of cumulative damage of airport cement concrete pavement ［J］.Engineering and Technological Research, 2021, 6(3): 15-16.
［21］徐林荣, 陈昀灏, 商拥辉, 等. 基于力学-经验模型的交通荷载作用下软基长期沉降计算［J］. 长安大学学报(自然科学版), 2021, 41(5): 1-10.
XU Linrong, CHEN Yunhao, SHANG Yonghui, et al. Long-term settlement calculation of soft soil foundation under traffic load based on mechanical-empirical model［J］. Journal of Changan University (Natural Science Edition), 2021, 41(5): 1-10.
［22］邹晶晶, 姜昌山, 史超. 从ACN-PCN到ACR-PCR(下)——ACR-PCR方法详解［EB/OL］. (2024-04-02)［2025-07-28］. https://mp. weixin.qq.com/s?_biz=Mzg4ODgxNzI4NA==&mid=2247505491&idx=3&sn=c04a7a4d2d910975a1ae 305bba98a86d&chksm=cff7c5b8f8804caee38cf745fee286fad26a0 b3a3157ca693d1f56e605 de1 fae4bb1ade543f8&cur_album_id=2465653669976489985&scene=189#wechat_redirect.
ZOU Jingjing, JIANG Changshan, SHI Chao. From ACN-PCN to ACR-PCR (Part 2) — A comprehensive explanation of the ACR-PCR method ［EB/OL］. (2024-04-02)［2025-07-28］.https://mp.weixin.qq.com/s?_biz=Mzg4OdgxNz I4NA==&mid=2247505491&idx=3&sn=c04a7a4d2d910975a1ae305bba98a86d& chksm=cff7c5b8f8804caee38cf745fee286fad26a0b3a3157ca693d 1f56e605de1fae4bb1ade543f8&cur_album_id=24656536699764 89985&scene=189#wechat_redirect.
［23］吕惠卿, 张湘伟, 成思源. 水泥混凝土路面力学性能研究综述［J］. 重庆大学学报(自然科学版), 2005, 28(6): 60-63.
LYU Huiqing, ZHANG Xiangwei, CHENG Siyuan. Study on mechanical properties of cement concrete pavements［J］. Journal of Chongqing University (Natural Science Edition), 2005, 28(6): 60-63.
［24］杨晓华, 姚卫星, 段成美. 确定性疲劳累积损伤理论进展［J］. 中国工程科学, 2003, 5(4): 81-87.
YANG Xiaohua, YAO Weixing, DUAN Chengmei. The review of ascertainable fatigue cumulative damage rule［J］. Engineering Science, 2003, 5(4): 81-87.

Evaluation of Airport Rigid Pavement Grades and Parameter Sensitivity

机场刚性道面等级评价与参数敏感性分析

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 1

Recommended Articles

Metrics