长寿命高性能耐候钢桥研究进展与工程应用

王春生; 张静雯; 段兰; 谭晨欣

doi:10.19818/j.cnki.1671-1637.2020.01.001

长寿命高性能耐候钢桥研究进展与工程应用

doi: 10.19818/j.cnki.1671-1637.2020.01.001

长安大学公路学院, 陕西西安 710064

基金项目:

国家"万人计划"科技创新领军人才支持项目 W03020659

交通运输部应用基础研究项目 2014319812080

陕西省创新人才推进计划科技创新团队项目 2019TD-022

中央高校基本科研业务费专项资金项目 300102219309

详细信息

作者简介:
王春生(1972-), 男, 黑龙江绥化人, 长安大学教授, 工学博士, 从事钢与组合结构桥梁研究

中图分类号: U448.36
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出版历程
- 收稿日期: 2019-08-04
- 刊出日期: 2020-02-25

Research progress and engineering application of long lasting high performance weathering steel bridges

School of Highway, Chang'an University, Xi'an 710064, Shaanxi, China

More Information

Author Bio:
WANGChun-sheng(1972-), male, professor, PhD, wcs2000wcs@163.com

摘要

摘要: 系统归纳与剖析了国内外耐候钢桥的研究新进展及工程应用情况, 总结了稳定耐候锈层的形成机制、选材标准、腐蚀与疲劳损伤机理、耐候构造、耐候螺栓研发以及锈层检测与评价技术等方面的关键科技成果, 梳理并完善了耐候钢桥的适用范围和腐蚀余量设计指标, 提出了耐候钢桥锈层稳定化处理及施工技术要点; 评析了耐候钢桥锈层损伤检测与评价技术、腐蚀损伤养管技术, 结合美、日耐候钢桥工程事故经验教训和中国首批长寿命高性能耐候钢桥建设技术创新成果, 探讨了该领域的技术创新方向。研究结果表明: 耐候锈层由外层的γ-FeOOH、α-FeOOH以及内层的非晶态FeOOH化合物与Fe₃O₄构成, 稳定耐候锈层能否形成与保持, 主要受氯离子、积水和积尘等因素的影响; 建议编制中国高性能耐候钢桥选材区划图谱, 完善稳定耐候锈层构造设计准则; 现代耐候钢桥具有高性能和长寿命的技术特征, 带锈层构造细节的面内应力疲劳、面外变形疲劳试验和数值断裂力学模拟, 以及耐候高强螺栓长期耐损性能研究的推进, 将为建立完善的耐腐蚀、抗疲劳设计准则奠定基础; 人工智能技术的应用将推动长寿命高性能耐候钢桥智能运维技术的重大进步; 应加大研发投入, 建立具有中国自主知识产权的长寿命高性能耐候钢桥设计、建造和运维标准规范体系, 培养高素质的工程技术人才, 推进交通强国建设。
- 桥梁工程 /
- 长寿命 /
- 高性能耐候钢 /
- 耐候螺栓 /
- 耐候锈层 /
- 耐候构造 /
- 疲劳 /
- 设计准则 /
- 智能运维
Abstract: The new research progress and engineering application of weathering steel bridges at home and abroad were systematically generalized and analyzed. The key scientific and technological achievements in the fields of formation mechanism of stable corrosion-resistant patina, material selection standard, corrosion and fatigue damage mechanism, research and development of corrosion-resistant configuration and weathering bolt, and detection and evaluation technology of patina were summarized. The application scope and corrosion allowance design indexes of weathering steel bridges were combed and improved, and the key points of stabilization treatment and construction technology for the patina of weathering steel bridges were proposed. The damage detection and evaluation technology and corrosion damage maintenance and management technology of patina in weathering steel bridges were evaluated and analyzed. Combined with the experience and lessons of weathering steel bridge engineering accidents in the United States and Japan, as well as the construction technological innovation achievements of the first batch of long lasting high performance weathering steel bridges in China, the technological innovation direction in this field was discussed. Research result shows that the composition of corrosion-resistant patina contains the outer layer of γ-FeOOH and α-FeOOH, and the inner layer of amorphous FeOOH compound and Fe₃O₄. The formation and durability of stable corrosion-resistant patina are mainly affected by the factors such as chloride ion, accumulated water and dust. The material selection zoning map of high performance weathering steel bridges in China is suggested to establish, and the configuration design criterion of stable corrosion-resistant patina should be improved. The modern weathering steel bridge has the technical characteristics of high performance and long lasting. The in-plane stress fatigue, out-of-plane deformation fatigue test, numerical fracture mechanics simulation of configuration details with patina and the research on the long-term damage resistance of weathering high-strength bolts should be promoted to lay the foundation for establishing a perfect design criterion of anti-corrosion and anti-fatigue. The application of artificial intelligence technology will promote the significant progress of intelligent management and maintenance technology of long lasting high performance weathering steel bridges. The investment for research and development should be increased, a specification system should be established for the design, construction and maintenance of long lasting high performance weathering steel bridges with independent intellectual property rights in China, the high-quality engineering and technical talents should be cultivated, thus to promot the development of Chinese strong transportation network.
- bridge engineering /
- long lasting /
- high performance weathering steel /
- weathering bolt /
- corrosion-resistant patina /
- corrosion-resistant configuration /
- fatigue /
- design criterion /
- intelligent operation and maintenance

HTML全文

图 1 腐蚀挂片试验装置

Figure 1. Corrosion coupon test device

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图 2 HPS485W挂片试样腐蚀前后形貌对比

Figure 2. Aappearance comparison of HPS485W coupon specimen before and after corrosion

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图 3 Fe的氧化反应

Figure 3. Oxidation reaction of Fe

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图 4 耐候钢基体上的锈层结构

Figure 4. Patina structure on weathering steel substrate

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图 5 CVN夏比冲击试样的破坏形态与韧-脆转变温度曲线

Figure 5. Failure patterns of CVN Charpy impact specimens and ductile-brittle transition temperature curves

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图 6 CTOD试样的塑性区

Figure 6. Plastic zone of CTOD specimen

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图 7 混合设计高强耐候钢工字梁抗弯性能试验

Figure 7. Bending performance test of high strength weathering steel Ⅰ-beam with hybrid design

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图 8 遮蔽条件下焊接耐候钢梁下翼缘疲劳裂纹

Figure 8. Fatigue cracks on bottom flange of welded weathering steel girder under sheltered condition

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图 9 面外变形疲劳试验装置与腹板间隙面外变形疲劳裂纹

Figure 9. Test device for out-of-plane deformation fatigue test and out-of-plane deformation fatigue cracks at web gaps

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图 10 应力比和间隙尺寸对腹板间隙面外变形细节疲劳强度的影响

Figure 10. Influences of stress ratio and gap size on out-of-plane deformation fatigue strength of web gap details

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图 11 JISF规范中规定的日本本土与冲绳地区适宜使用耐候钢的区域

Figure 11. Areas of Japan and Okinawa where suitable for weathering steel specified in JISF code

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图 12 隧道效应

Figure 12. Tunnel like effect

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图 13 日本技术标准中建议的下翼缘构造

Figure 13. Bottom flange configuration proposed by Japan technical standards

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图 14 竖向加劲肋构造(单位: mm)

Figure 14. Vertical stiffener configurations (unit: mm)

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图 15 Yamada建议的竖向加劲肋构造

Figure 15. Vertical stiffener configuration suggested by Yamada

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图 16 焊接工艺评定试样

Figure 16. Specimens for evaluation of welding process

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图 17 高强耐候螺栓及连接

Figure 17. High strength weathering bolts and connections

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图 18 沈阳后丁香大桥

Figure 18. Houdingxiang Bridge in Shenyang

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图 19 眉县常兴二号桥

Figure 19. Changxiong No.2 Bridge in Meixian County

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图 20 钢梁整体吊装

Figure 20. Integral hoisting of steel girder

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图 21 主梁横断面

Figure 21. Cross section of main girder

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图 22 陕西黄延高速磨坊跨线桥

Figure 22. Huangyan Freeway Mofang Viaduct in Shaanxi

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图 23 排水措施不合理导致钢梁与混凝土桥台结合处局部锈蚀

Figure 23. Local corrosion at connection between steel girder and concrete abutment caused by unreasonable drainage facilities

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图 24 未形成稳定锈层导致锈液流淌到墩台上

Figure 24. Patina fluid in unstable patina flowing onto pier and abutment

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图 25 耐候钢跨线桥

Figure 25. Weathering steel bridge crossing highway

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图 26 耐候钢表面锈层松散、片状脱落

Figure 26. Loosing and flaking of patina on weathering steel surface

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图 27 腐蚀劣化的日本耐候钢桥

Figure 27. Corrosion and deterioration of weathering steel bridge in Japan

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图 28 耐候钢主梁内侧严重腐蚀

Figure 28. Serious corrosion inside weathering steel main girder

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表 1 中国耐候钢桥

Table 1. Weathering steel bridges in China

桥名	桥梁用途	结构形式	跨径组成/m	涂装情况	主要构件材质	开通时间
京广铁路武汉巡司河桥	铁路桥	钢箱梁桥	3×19.3	钢梁免涂装	NHq35	1991
沈阳后丁香大桥	公路桥	钢箱梁桥	38+61+38、38+61+61+48、48+61+38	箱内免涂装	Q345qENH	2013
陕西眉县常兴二号桥	公路桥	管翼缘组合梁桥	54	全桥免涂装	下翼缘Q500qDNH, 其余Q345qDNH	2014
陕西黄延高速磨坊跨线桥(K16+322.607)	公路桥	钢板梁桥	2×28	全桥免涂装	下翼缘Q500qENH, 其余Q345qENH	2015
陕西黄延高速磨坊跨线桥(K18+496.141)	公路桥	管翼缘组合梁桥	2×28	全桥免涂装	下翼缘Q500qENH, 其余Q345qENH	2015
西藏墨脱达国大桥	公路桥	钢桁架悬索桥	81	主桁免涂装	Q345qDNH	2015
西藏墨脱西莫河大桥	公路桥	钢桁架悬索桥	126	主桁免涂装	Q345qDNH	2015
台州内环路立交桥	公路桥	钢箱梁桥	45~61	箱内免涂装	Q345qDNH	2017
拉林铁路藏木雅鲁藏布江大桥	铁路桥	中承式钢管混凝土提篮拱桥	430	桥面以上钢管拱免涂装	主钢管Q420qENH, 其余Q345qDNH	2019
官厅水库特大桥	公路桥	双塔单跨悬索桥	210+720+210	主桥加劲钢板梁免涂装	Q345qENH	2019
G109线改建工程跨柳忠高速高架桥	市政桥	钢管翼缘斜弯组合梁桥	51+61+51	全桥免涂装	下翼板Q500qENH, 其余Q345qENH	2020

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表 2 日本可使用耐候钢的地区

Table 2. Areas of Japan where weathering steel can be used

地区		与海岸线距离/km
日本海的沿海地区	Ⅰ	> 20
	Ⅱ	> 5
太平洋海岸		> 2
濑户内海沿岸		> 1

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表 3 EN ISO 9223—2012中的环境等级分类

Table 3. Classification of environmental grades in EN ISO 9223—2012

环境等级	环境特征
C1	仅室内环境
C2	大气中含有少量污染物, 多为农村地区
C3	含有中等SO₂含量污染物的城市和工业环境, 含少量盐的海岸地区
C4	含有中等盐含量的工业和海岸地区
C5-I	湿度高、腐蚀较严重的工业地区
C5-M	盐含量较高的海岸及近海地区

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表 4 BD 7/01—1981中规定的各环境等级下的腐蚀余量

Table 4. Corrosion allowances under each environmental grade in BD 7/01—1981

环境等级	腐蚀等级	腐蚀余量/mm
C1、C2、C3	中级	1.0
C4、C5	严重	1.5
箱梁内部		0.5

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表 5 德国、瑞典技术标准中建议的腐蚀余量

Table 5. Corrosion allowances recommended in Germany and Sweden techincal standards mm

环境等级	C2	C3	C4
德国标准	0.8	1.2	1.5
瑞典标准	0.6	1.2	1.7

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表 6 t_v的取值

Table 6. Values of t_v

钢板厚度/mm	EN 10029—1991中厚度允许容差分类下t_v的取值/mm
钢板厚度/mm	类别A	类别B	类别C	类别D
(5, 8]	0.05	0.15	0.45	-0.15
(8, 15]	0.10	0.25	0.60	-0.25
(15, 25]	0.15	0.45	0.75	-0.20
(25, 40]	0.25	0.75	1.05	-0.10
> 40	0.40	1.10	1.40	0.10

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表 7 耐候钢最低预热温度建议值

Table 7. Recommended values of minimum preheating temperature for weathering steel

耐候钢牌号	不同接头最大板厚(mm)的最低预热温度建议值/℃
耐候钢牌号	[20, 40]	(40, 60]	(60, 80]	> 80
Q345qNH		50	80	100
Q420qNH		65	100	120
Q500qNH	80	100	120	150

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表 8 日本耐候高强螺栓化学成分(F10TW级)

Table 8. Chemical compositions of weathering high-strength bolts in Japan(F10TW grade)

螺栓名称

C含量/%

Si含量/%

Mn含量/%

P含量/%

S含量/%

Cr含量/%

Ni含量/%

Cu含量/%

Mo含量/%

Ti含量/%

B含量/%

I指数

KHB10W

0.20

0.30

0.80

0.010

0.80

0.55

0.43

0.10

≤0.05

≤0.003

6.97

NWB110

0.20~0.25

0.15~0.25

0.70~0.90

≤0.03

0.6~0.8

0.30~0.50

0.3~0.5

0.001~0.003

6.74

JFE

0.23

0.14

0.82

0.010

0.83

0.47

0.42

0.20

6.77

0.20~0.30

0.15~0.35

0.60~0.90

≤0.03

≤0.035

0.7~0.9

0.35~0.55

0.3~0.5

0.005~0.04

0.001~0.003

6.97

SNC22BA

0.20~0.25

0.10~0.20

0.70~0.90

≤0.03

0.7~0.9

0.30~0.60

0.3~0.6

0.003

6.55

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表 9 日本耐候钢桥锈层外观评定分级

Table 9. Appearance classification of patina for weathering steel bridges in Japan

表 10 Iowa州交通厅建议的锈层量化分级标准

Table 10. Quantitative classification standard of patina recommended by Iowa Department of Transportation

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