Static and Dynamic Four-Point Flexural Tests of Concrete Beams with Variation in Concrete Quality, Reinforcement Properties and Impact Velocity

1. Magnusson J: “Shear in Concrete Structural Elements Subjected to Dynamic Loads”. PhD Thesis, KTH Royal Institute of Technology, Dept. of Concrete Structures, Stockholm, Sweden, 2019, 160 pp. Search in Google Scholar

2. Chopra A K: “Earthquake Response of Inelastic Systems”. Chapter 7, “Dynamics of Structures”, Pearson, Harlow, UK, 2017, pp. 243-291. Search in Google Scholar

3. Hanoon A N, Jaafar M S, Hejazi F & Aziz F N A A: “Energy Absorption Evaluation of Reinforced Concrete Beams under Various Loading Rates Based on Particle Swarm Optimization Technique”. Engineering Optimization, No. 49, 2017, pp. 1483-1501.10.1080/0305215X.2016.1256729 Search in Google Scholar

4. Chen W F: “Elastic Perfectly Plastic Fracture Models”. Chapter 6, “Plasticity in Reinforced Concrete Structures”, J. Ross Publishing, Florida, USA, 2007, pp. 253-294. Search in Google Scholar

5. Mosley W H & Bungey J H: “Design of Reinforced Concrete Beams”. Chapter 7, “Reinforced Concrete Design”, The Macmillan Press Ltd, London, UK, 1982, pp. 152-192.10.1007/978-1-349-16888-0_7 Search in Google Scholar

6. Fortifikationsförvaltningen: “ Instructions for Design of Reinforced Concrete Structures as Protection Against the Action of Conventional Weapons in the Immediate Area”. (“Anvisningar för Dimensionering av Armerade Betongkonstruktioner som Skydd mot Verkan av Konventionella Vapen inom Närmissområde”). Stockholm, Sweden, 1973, Publ nr 25:1, 85 pp. (In Swedish). Search in Google Scholar

7. Ansell A & Svedbjörk G: “Static Testing of Simply Supported Concrete Strips with Reinforcement of Varying Ductility (2000:16)”. (“Statisk Provning av Fritt Upplagda Plattstrimlor av Betong med Armering av Varierande Seghet (2000:16)”). Stockholm, Sweden, 2000, 50 pp. (In Swedish). Search in Google Scholar

8. Ansell A & Svedbjörk G: “Dynamic Testing of Simply Supported Concrete strips with Reinforcement of Varying Ductility (2001:15)”. (“Dynamisk Provning av Fritt Upplagda Plattstrimlor av Betong med Armering av Varierande Seghet (2001:15)”). Stockholm, Sweden, 2001, 60 pp. (In Swedish). Search in Google Scholar

9. Ansell A & Svedbjörk G: “Static and Dynamic Testing of Simply Supported Concrete Strips with Reinforcement of Varying Ductility (2003:8)”. (“Statisk och Dynamisk Provning av Fritt Upplagda Plattstrimlor av Betong med Armering av Varierande Seghet (2003:8)”). Stockholm, Sweden, 2003, 63 pp. (In Swedish). Search in Google Scholar

10. Ansell A & Svedbjörk G: “Static and Dynamic Testing of Concrete Strips Reinforced with Steel of Stiff and Soft Quality”. Nordic Concrete Research: Research projects 2002, Helsingör, Sweden, 2002, pp. 45-47. Search in Google Scholar

11. Ansell A & Svedbjörk G: “Static Testing of Simply Supported Plate Strips with Varying Cross-Sectional Areas (2005: 6)”. (“Statisk Provning av Fritt Upplagda Plattstrimlor med Varierande Tvärsnittsareor (2005:6)”). Stockholm, Sweden, 2005, 64 pp. (In Swedish). Search in Google Scholar

12. Ansell A & Svedbjörk G: “Static Testing of Continuous Concrete Strips with Reinforcement of Varying Ductility (2001:9)”. (“Statisk Provning av Kontinuerliga Plattstrimlor av Betong med Armering av Varierande Seghet (2001:9)”). Stockholm, Sweden, 2001, 52 pp. (In Swedish). Search in Google Scholar

13. Ansell A & Svedbjörk G: “Dynamic Testing of Continuous Concrete Strips with Reinforcement of Varying Ductility (2002:9)”. (“Dynamisk Provning av Kontinuerliga Plattstrimlor av Betong med Armering av Varierande Seghet (2002:9)”). Stockholm, Sweden, 2002, 43 pp. (In Swedish). Search in Google Scholar

14. Ansell A & Svedbjörk G: “Complementary Dynamic Testing of Continuous Concrete Strips with Reinforcement of Varying Ductility (2003:3)”. (“Kompletterande Dynamisk Provning av Kontinuerliga Plattstrimlor av Betong med Armering av Varierande Seghet (2003:3)”). Stockholm, Sweden, 2003, 57 pp. (In Swedish). Search in Google Scholar

15. Peterson V & Ansell A: “Evaluation of Dynamically Tested Concrete Beams Reinforced with Stiff and Mild Steel Qualities”. Proceedings, XXIV Concrete Research Symposium, Sandefjord, Norway, August 2021. (Submitted) Search in Google Scholar

16. Byggstandardiseringen: “Swedish Standard SS 13 72 10, Concrete Testing – Hardened Concrete – Cube Strength”. (“Svensk Standard SS 13 72 10, Betongprovning – Hårdnad Betong – Kubhållfasthet”). Stockholm, Sweden, 2003. (In Swedish). Search in Google Scholar

17. Ihueze C C & Enetanya A N: “Energy Absorption and Strength Evaluation for Compressed Glass Fibre Reinforced Polyester (GRP) for Automobile Components Design in Crash Prevention Scheme”. Journal of Minerals and Materials Characterization and Engineering, No. 1, 2012, pp. 85-105.10.4236/jmmce.2012.111007 Search in Google Scholar

18. Johansson M: “Structural Behaviour in Concrete Frame Corners of Civil Defence Shelters”. PhD Thesis, Chalmers University of Technology, Dept. of Structural Engineering, Göteborg, Sweden, 2000, 242 pp. Search in Google Scholar

19. Johansson M & Laine L: “The Capacity of the Urban Environment Against Extreme Dynamic Action – Part 3: Capacity of Structures”. (“Bebyggelsens Motståndsförmåga mot Extrem Dynamisk Belastning – Del 3: Kapacitet hos Byggnader”). Göteborg, Sweden, 2012, 101 pp. (In Swedish). Search in Google Scholar

20. Von Karman T & Duwez P: “The Propagation of Plastic Deformation in Solids”. Journal of Applied Physics, No. 21, 1950, pp. 987-994.10.1063/1.1699544 Search in Google Scholar

21. Meyers M A: “Elastic Waves”. Chapter 2, “Dynamic Behaviour of Materials”, John Wiley & Sons, Inc., New York, USA, 1994, pp. 23-65.10.1002/9780470172278.ch2 Search in Google Scholar

22. Ding C, Yang R & Feng C: “Stress Wave Superposition Effect and Crack Initiation Mechanism Between Two Adjacent Boreholes”. International Journal of Rock Mechanics and Mining Services, No. 138, 2021, pp. 1-9.10.1016/j.ijrmms.2021.104622 Search in Google Scholar