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CHEN, Gong, XIE. MICRO RENEWAL OF PUBLIC SPACE IN OLD COMMUNITIES BASED ON SHARING CONCEPT[J]. INDUSTRIAL CONSTRUCTION, 2020, 50(1): 80-83,90. doi: 10.13204/j.gyjz202001014
Citation: DENG Jun, LI Junhui, GUO Dong. A Review of Durability Research of Notched Steel Beams Reinfoned with Prestressed CFRP[J]. INDUSTRIAL CONSTRUCTION, 2024, 54(6): 81-90. doi: 10.3724/j.gyjzG24042801

A Review of Durability Research of Notched Steel Beams Reinfoned with Prestressed CFRP

doi: 10.3724/j.gyjzG24042801
  • Received Date: 2024-04-28
    Available Online: 2024-06-24
  • Fatigue cracking is one of the most common issue that damages the serviceability of steel bridges. Prestressed carbon fiber-reinforced polymer (CFRP) materials can effectively inhibit crack propagation, thereby extending the service life of structures. In prestressed CFRP-reinforced steel beams, the interface between CFRP and steel interface serves as the primary load transfer path, ensuring the mechanical properties and durability of the reinforced structure. However, under the influence of fatigue and hygrothermal environments, the bonding performance of the interface between CFRP and steel may tend to degrade, leading to the degradation of mechanical properties in the reinforced structure. This paper summarized the results of static and fatigue performance tests of steel beams with different prestressed strengthening system design schemes, as well as the degree of influence of environmental factors on structural performance, based on existing research. Additionally, this paper compiled formulas for calculating the interface principal stress and energy release rate of damaged steel beams reinforced with prestressed CFRP, and proposed methods for predicting the bearing capacity reduction coefficient and service life of reinforced steel beams under fatigue loading and hygrothermal environments, as well as structural reinforcement design strategies considering interface durability.
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    Created with Highcharts 5.0.7Chart context menuAccess Area Distribution其他: 3.4 %其他: 3.4 %其他: 1.2 %其他: 1.2 %China: 1.2 %China: 1.2 %Hong Kong, China: 0.9 %Hong Kong, China: 0.9 %[]: 0.6 %[]: 0.6 %上海: 2.8 %上海: 2.8 %东莞: 0.6 %东莞: 0.6 %北京: 8.9 %北京: 8.9 %南京: 1.2 %南京: 1.2 %南通: 0.3 %南通: 0.3 %台州: 0.6 %台州: 0.6 %合肥: 0.6 %合肥: 0.6 %嘉兴: 0.3 %嘉兴: 0.3 %大连: 1.2 %大连: 1.2 %天津: 0.6 %天津: 0.6 %太原: 0.6 %太原: 0.6 %宿州: 0.3 %宿州: 0.3 %广州: 0.6 %广州: 0.6 %张家口: 0.9 %张家口: 0.9 %成都: 0.9 %成都: 0.9 %扬州: 0.6 %扬州: 0.6 %晋城: 0.3 %晋城: 0.3 %朝阳: 1.2 %朝阳: 1.2 %杭州: 3.7 %杭州: 3.7 %武汉: 1.2 %武汉: 1.2 %泰安: 0.3 %泰安: 0.3 %济南: 0.3 %济南: 0.3 %济宁: 0.3 %济宁: 0.3 %温州: 0.3 %温州: 0.3 %湖州: 0.9 %湖州: 0.9 %漯河: 1.2 %漯河: 1.2 %珠海: 0.3 %珠海: 0.3 %石家庄: 0.6 %石家庄: 0.6 %福州: 0.9 %福州: 0.9 %芒廷维尤: 45.9 %芒廷维尤: 45.9 %荆州: 0.3 %荆州: 0.3 %菏泽: 0.3 %菏泽: 0.3 %衢州: 0.3 %衢州: 0.3 %西宁: 4.9 %西宁: 4.9 %贵阳: 0.3 %贵阳: 0.3 %运城: 2.8 %运城: 2.8 %邯郸: 0.3 %邯郸: 0.3 %郑州: 3.1 %郑州: 3.1 %重庆: 0.3 %重庆: 0.3 %镇江: 0.3 %镇江: 0.3 %长沙: 0.6 %长沙: 0.6 %阳泉: 0.6 %阳泉: 0.6 %其他其他ChinaHong Kong, China[]上海东莞北京南京南通台州合肥嘉兴大连天津太原宿州广州张家口成都扬州晋城朝阳杭州武汉泰安济南济宁温州湖州漯河珠海石家庄福州芒廷维尤荆州菏泽衢州西宁贵阳运城邯郸郑州重庆镇江长沙阳泉

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