Continuous beams have the capability to redistribute internal forces due to their indeterminate structural features, leading to enhanced beam deformability, reduced reinforcement congestion and more effective cross-section capacity usage. Thus, continuous reinforced concrete (RC) beams are popular members in most structures. However, RC structures located in corrosive environments might be degraded due to steel reinforcement corrosion. In this study, a recently proposed dual-functional intervention method, impressed current cathodic protection and structural strengthening (ICCP-SS), is adopted to repair degraded beams. The carbon fabric-reinforced cementitious matrix (C-FRCM) composite serves dual functions in the intervention method. The effects of reinforcement corrosion, cathodic protection and the C-FRCM strengthening system on the behaviors of continuous beams should be investigated. The aims of this study are to provide experimental data of continuous RC beams rehabilitated by ICCP-SS technology in corrosive environments and to investigate the structural responses, moment redistributions and design rules of these beams. This paper includes an experimental program, a discussion of the results and a design proposal. The results of electrochemical monitoring showed that the steel reinforcements in continuous beams under corrosive environments are successfully
International audienceRecent developments in powder technology gave birth to a new lubricant – powder lubricant. Compared to liquid lubricant, powder lubricant like graphite powder has several advantages, such as good electrical conductivity and good thermal resistance. Such advantages are especially appreciated in sliding electrical contacts. Thus, the study of the electrical transmission ability of a shearing powder layer under different dy-namical constraints appears to have a great interest. Recent works allowed to model the coupling of mechanical and electrical effects in a discrete medium. This algorithm was extended to study the electrical properties of a shearing powder layer with Discrete Element Method. The mechanical and electrical behaviors of the sample were studied in different dynamical regimes, characterized by the inertial number I. The results exhibit an interesting relationship between the average contact resistance and the inertial number I. An exponential increase of the sample's electrical resistance as well as the induced electrical noise are observed closed to the dense flow limit. Such observations underline the fact that to ensure the electrical transmission ability of the powder layer, one must keep the particle size and shear rate small, and a sufficiently large pressure
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