Carbon fiber wraps can be used for strengthening concrete and steel structures by increasing strength and corrosion resistance, with advantages of high strength, low weight, and speed of installation. Applications include strengthening pipes, columns, beams, and walls for seismic activity, added loads, corrosion, fatigue, and repairs from cutting or drilling. Engineering support is available and examples provided strengthening infrastructure for water, sewer, power plants, and other industrial facilities.
Carbon Fiber (FRP) used for structural strengthening. It’s 5 to 10 times stronger than steel, light weight and corrosion resistant. The ASME PCC-2 code new standard includes carbon fiber as an acceptable repair and strengthen system for steel pipes.
Fiber Reinforced Polymer (Frp) Composites Rebar Steven Tyler
Mission - Promote the use and growth of FRP reinforcement (rebar, tendons & grids) in concrete and masonry applications through development of quality procedures, industry specifications, performance standards, and field application guidelines.
http://www.bpcomposites.com/
The presentation includes difference between repair, retrofitting and rehabilitation. methods of repairs, repair materials, various methods for retrofitting etc.
Carbon Fiber (FRP) used for structural strengthening. It’s 5 to 10 times stronger than steel, light weight and corrosion resistant. The ASME PCC-2 code new standard includes carbon fiber as an acceptable repair and strengthen system for steel pipes.
Fiber Reinforced Polymer (Frp) Composites Rebar Steven Tyler
Mission - Promote the use and growth of FRP reinforcement (rebar, tendons & grids) in concrete and masonry applications through development of quality procedures, industry specifications, performance standards, and field application guidelines.
http://www.bpcomposites.com/
The presentation includes difference between repair, retrofitting and rehabilitation. methods of repairs, repair materials, various methods for retrofitting etc.
A 4 Days Site Visit Report on Green Building Constructing in DEI I Sustainabl...Gaurav Verma
This report presents how bamboos can be used to construct a Green building. It also covers treatment of bamboos, detailing of bamboo columns, roof trusses, timber beams, and floor construction.
I was hired by a real estate company to clean and clear up a green swimming pool at a home located near Brandon, Florida. The work included cleaning up the surrounding deck area, tile, equipment area, and some minor repair work.
A 4 Days Site Visit Report on Green Building Constructing in DEI I Sustainabl...Gaurav Verma
This report presents how bamboos can be used to construct a Green building. It also covers treatment of bamboos, detailing of bamboo columns, roof trusses, timber beams, and floor construction.
I was hired by a real estate company to clean and clear up a green swimming pool at a home located near Brandon, Florida. The work included cleaning up the surrounding deck area, tile, equipment area, and some minor repair work.
CoroBrick will provide both customers the benefits of a longer-lasting, corrosion resistant lining system that will hold up to their unique environmental challenges.
Discover how you can use concrete lego blocks to solve many civil engineering problems. Learn how to value engineer your next project with concrete lego blocks. They are excellent for the construction of a number of retaining walls including, gravity retaining walls, reinforced block retaining walls and inclined retaining walls
Retrofitting of RC members and repair works.pptxDP NITHIN
Introduction to Retrofitting, Needs and methodology of Retrofitting, Retrofitting techniques, Strengthening of RC members, water proof treatment and also about the effective management of old structures
9. Cholla Power Plant Situation: The 66" circ line had experienced enough wire breaks that a possible rupture was a major concern. The original repair was only 40-60 linear feet depending on the condition of the pipe. We needed to be able to restore the pressure bearing capacity of the circ line, the overburden was only 8’. Challenges: Time restraint was a major factor, this job there was only a small window of time to do the entire job. The prep work for the job was limited to only within 2 weeks. To remove and replace the line would have involved too much time and disruption of the existing above ground infrastructure. Likewise external tensioning would have taken too long with too much disruption.
10. Solution: We went ahead and came up with a comparable solution that would not affect any of the above ground infrastructure and still provide the needed support. Carbon fiber was installed in two layers of 20 oz unidirectional in a hoop direction. Conclusion: The original 40 linear feet was done in 2 days. After the completion of the work, APS requested us to complete an additional 120 lf. We mobilized within 72 working hours and completed the additional 120 lf within 5 days.
11.
12. Solution: It was decided to install 20 oz of unidirectional carbon fiber in hoop direction, because this solution can be done quickly and with little invasiveness. Another supporting reason was because the risk of corrosion would be nonexistent. Conclusion: Before installation took place it was discovered that there were severe cracks where the carbon fiber was to be installed in the hoop direction. 20 oz of carbon fiber was installed perpendicular to the cracks before installing in the hoop direction to help maintain the integrity of the pipe. The job was completed in the time required and is still functioning today.
13.
14.
15.
16.
17.
18. The Solution After several solutions were investigated, it was determined that seismic reinforcement could best be achieved with carbon-fiber composites applied to the exterior and interior wall surfaces. North side of building after sandblasting to remove paint in areas where carbon-fiber is to be installed. Front entrance is shown with windows removed and surface sandblasted, now ready for 2 layers of fabric to be installed
19. The Results The application of carbon-fiber fabrics and laminates proved to be the least expensive and most effective way to provide seismic reinforcement. The client was very satisfied with the product and job coordination. Realizing the challenges the crew faced doing this in the summer when the temperature was between 110 and 120 degrees. The job was completed in time for the school to reopen for classes the end of July. Shown below the crew is installing carbon-fiber laminates on the interior walls and openings. This shows the front entry after the application of bi-directional fabrics. Stucco was later added then painted.
20.
21.
22. The Solution Fill the old penetrations that were not to be reused. Install 4” wide carbon fiber laminate strips to the underside of the planks in the areas where the penetrations had been filled. At the areas where the new plumbing was protruding we overlaid 12” wide carbon fiber fabric strips in a cross hash pattern over the laminate going 24” past the plumbing on all sides.
23. The Results The strength lost because of the penetrations and the post tension cables being cut was restored. This allowed the restoration to continue at a great cost saving over replacing the floor planks. Which would have been an enormous construction issue at best.
24.
25. The Solution Install one layer of uni-directional carbon fiber fabric the full width of the beams and wrapping the complete beam. It was determined that any beam with a core 8 ½” or less from the bottom of the beam need carbon fiber support. This replaced the 35 kips structural strength lost by the cores while maintaining the ceiling height in the hallways.
26. The Results Because some of the plumbing had already been installed the fabric had to be cut to allow the installers to wrap the fabric around the pipes. A second layer of fabric was installed over the cuts in a horizontal direction to prevent lose of strength from the cuts. The job was completed in 2 weeks and the contractor was able to get back on schedule with construction.
30. Roger Road Treatment Plant Situation: The digestive gasses eroded the existing concrete columns and deteriorated the existing reinforcement. Challenges: The sludge digester needed to be kept free of rocks and pebbles. The floor of the digester was slanted making scaffolding a challenge and more difficult to keep debris out.
31. Solution: Installers from the Arizona Repair Masons' Specialty Crew reinforced deteriorated columns with carbon fiber composites inside the drained digester tank of the sewage treatment plant. Damaged rebar was augmented with fiberglass rebar. Conclusion: Company was happy with the end results of restoration to the columns. Columns being wrapped with Carbon fiber laminates in order to reinforce the eroded areas.
32.
33. Added Touch Warehouse Badly spalled and deteriorated columns due to years of water coming from the scuppers with no down spouts.
34.
35.
36. Central Stores—City of Phoenix Situation: The wood beams that support the roof had been deflecting over a few years. The problems are exacerbated with the ponding of rain water in the dips created from the deflections. There were approximately 190 beams that required strengthening . The Owner (The City of Phoenix) wanted us to arrest any continued deflections and increase the margin of safety for the users. Challenges: Work in the space was to continue without shutting down the users. Air conditioning replacement was going on simultaneously which caused poor ventilation.
37. Solution: Carbon fiber laminate reinforcing with fiberglass fabric stirrups were used. The Carbon laminates provide continuous adhesive reinforcing. The laminates were placed in the middle 8' of the beams, where the deflection was the greatest on the tension face. The glass fabrics were used to eliminate shear stresses on the ends and to transfer the tensile force of the laminates up through the natural axis.
38. Conclusion: Arizona Repair Masons helped insure that the original engineering was adequate to meet the loads with acceptable deflection by insisting that the original calcs be checked. Workers used respirators during operations. The overstress on the beams was reduced to less than .07% and the ponds on the roof were filled in with foam to shed future water.