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Pullout resistance of inclined anchors embedded in geogrid reinforced sand
https://orcid.org/0000-0002-1873-6388
Abstract Transmission tower foundations experience large vertical uplift forces during their lifetime. These forces can be resisted by providing anchor foundations below the tower. In this study, laboratory experiments were conducted to investigate the pullout capacity of inclined plate anchors in dry sand. The capacity of inclined anchor significantly improved in the presence of geogrid reinforcement on top of the anchor plate. Besides, the pullout capacity increased with the inclination angle (30°, 45°, 60°) both in unreinforced and reinforced soil. It was observed that the ultimate pullout load is significantly influenced by the embedment depth of the anchor plate and relative density of the backfill material. The experimental results were compared with a three-dimensional numerical model developed in . The comparison shows good agreement between the experimental and numerical results, and the numerical model can predict the pullout behaviour of the inclined anchor plate both in unreinforced and reinforced soil. Comparison of uplift resistance of pile and anchor foundations are shown through a design example of a transmission tower foundation. Results indicate that inclined anchors embedded in reinforced soil can resist the uplift forces at shallow depth compared to piles.
Highlights Experiments were conducted to investigate the pullout behaviour of inclined achors in unreinforced and reinforced sand. The pullout capacity of inclined anchors were found to increase due to geogrid reinforcement on top of the plate anchor. The ultimate pullout load increased with an increase in the inclination angle of the anchor plate. The pullout capacity was also affected by the inclination angle of the anchor plate and the relative density of the sand. A three-dimensional numerical model is developed and the results were compared with the experimental data. A practical design example is presented for transmission tower foundation to compare inclined anchor foundations with piles.
Pullout resistance of inclined anchors embedded in geogrid reinforced sand
https://orcid.org/0000-0002-1873-6388
Abstract Transmission tower foundations experience large vertical uplift forces during their lifetime. These forces can be resisted by providing anchor foundations below the tower. In this study, laboratory experiments were conducted to investigate the pullout capacity of inclined plate anchors in dry sand. The capacity of inclined anchor significantly improved in the presence of geogrid reinforcement on top of the anchor plate. Besides, the pullout capacity increased with the inclination angle (30°, 45°, 60°) both in unreinforced and reinforced soil. It was observed that the ultimate pullout load is significantly influenced by the embedment depth of the anchor plate and relative density of the backfill material. The experimental results were compared with a three-dimensional numerical model developed in . The comparison shows good agreement between the experimental and numerical results, and the numerical model can predict the pullout behaviour of the inclined anchor plate both in unreinforced and reinforced soil. Comparison of uplift resistance of pile and anchor foundations are shown through a design example of a transmission tower foundation. Results indicate that inclined anchors embedded in reinforced soil can resist the uplift forces at shallow depth compared to piles.
Highlights Experiments were conducted to investigate the pullout behaviour of inclined achors in unreinforced and reinforced sand. The pullout capacity of inclined anchors were found to increase due to geogrid reinforcement on top of the plate anchor. The ultimate pullout load increased with an increase in the inclination angle of the anchor plate. The pullout capacity was also affected by the inclination angle of the anchor plate and the relative density of the sand. A three-dimensional numerical model is developed and the results were compared with the experimental data. A practical design example is presented for transmission tower foundation to compare inclined anchor foundations with piles.
Pullout resistance of inclined anchors embedded in geogrid reinforced sand
https://orcid.org/0000-0002-1873-6388
Abstract Transmission tower foundations experience large vertical uplift forces during their lifetime. These forces can be resisted by providing anchor foundations below the tower. In this study, laboratory experiments were conducted to investigate the pullout capacity of inclined plate anchors in dry sand. The capacity of inclined anchor significantly improved in the presence of geogrid reinforcement on top of the anchor plate. Besides, the pullout capacity increased with the inclination angle (30°, 45°, 60°) both in unreinforced and reinforced soil. It was observed that the ultimate pullout load is significantly influenced by the embedment depth of the anchor plate and relative density of the backfill material. The experimental results were compared with a three-dimensional numerical model developed in . The comparison shows good agreement between the experimental and numerical results, and the numerical model can predict the pullout behaviour of the inclined anchor plate both in unreinforced and reinforced soil. Comparison of uplift resistance of pile and anchor foundations are shown through a design example of a transmission tower foundation. Results indicate that inclined anchors embedded in reinforced soil can resist the uplift forces at shallow depth compared to piles.
Highlights Experiments were conducted to investigate the pullout behaviour of inclined achors in unreinforced and reinforced sand. The pullout capacity of inclined anchors were found to increase due to geogrid reinforcement on top of the plate anchor. The ultimate pullout load increased with an increase in the inclination angle of the anchor plate. The pullout capacity was also affected by the inclination angle of the anchor plate and the relative density of the sand. A three-dimensional numerical model is developed and the results were compared with the experimental data. A practical design example is presented for transmission tower foundation to compare inclined anchor foundations with piles.
Pullout resistance of inclined anchors embedded in geogrid reinforced sand
Mukherjee, Sougata (author) / Kumar, Lucky (author) / Choudhary, Awdhesh Kumar (author) / Babu, G.L. Sivakumar (author)
Geotextiles and Geomembranes ; 49 ; 1368-1379
2021-05-17
12 pages
Article (Journal)
Electronic Resource
English
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