Deflection of Steel Reinforced Concrete Beam Prestressed With CFRP Bar

Carbon Fiber Reinforced polymer (CFRP) bars are weak in yielding property which results in sudden failure of structure at failure load. Inclusion of non-pretensioned steel reinforcement in the tension side of CFRP based prestressed concrete beam will balance the yielding requirements of member and it will show the definite crack failure pattern before failure. Experimental investigation has been carried out to study the deflection behavior of partially prestressed beam. Experimental works includes four beam specimens stressed by varying degree of prestressing. The Partial Prestressing Ratio (PPR) of specimen is considered for experimental works in the range of 0.6 to 0.8. A new deflection model is recommended in the present study considering the strain contribution of CFRP bar and steel reinforcement for the fully bonded member. New deflection model converges to experimental results with the error of less than 5%

Deflection of Steel Reinforced Concrete Beam Prestressed with CFRP Bar

Carbon Fiber Reinforced polymer (CFRP) bars are weak in yielding property which results in sudden failure of structure at failure load. Inclusion of non-pretensioned steel reinforcement in the tension side of CFRP based prestressed concrete beam will balance the yielding requirements of member and it will show the definite crack failure pattern before failure. Experimental investigation has been carried out to study the deflection behavior of partially prestressed beam. Experimental works includes four beam specimens stressed by varying degree of prestressing. The Partial Prestressing Ratio (PPR) of specimen is considered for experimental works in the range of 0.6 to 0.8. A new deflection model is recommended in the present study considering the strain contribution of CFRP bar and steel reinforcement for the fully bonded member. New deflection model converges to experimental results with the error of less than 5%

Callus induction, somatic embryogenesis and plant Regeneration in cotton (gossypium hirsutum l.)

Cotton is an important fibre crop of the world and it is also a good source of oil and high quality protein meal. Somaticembryogenesis in cotton plays a key role in cotton transformation. Somatic embryogenesis forms the basis of cellulartotipotency in higher plants. Four cotton cultivars viz., MCU 5, MCU 12, MCU 13 and SVPR 2 along with two modelvarieties viz., Coker 310 and Coker 312 were used to assess the somatic embryogenic efficiency. Hypocotyl and cotyledonaryleaves were used as explants for callus induction. Hypocotyl was found to be the best for in vitro study. Coker 312, MCU 13,Coker 310 and MCU 12 responded well for callus induction. Coker lines alone responded well for somatic embryogenesis.The best medium for proliferation of callus was standardized as MS + 0.1 mgl-1 2,4-D + 0.5 mgl-1 kinetin. Among thedifferent combinations tried, MS + 1.9 gl-1 KNO3 was found suitable for somatic embryogenesis. An efficient protocol forthe production of high frequency of callus and somatic embryos of cotton has been developed