P. Chakravarthy scite author profile

P. Chakravarthy

5Publications

87Citation Statements Received

125Citation Statements Given

How they've been cited

119

How they cite others

116

Affiliations

Indian Institute of Space Science and Technology, Vels University, Indian Institute of Technology Madras

Publications

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High glass-transition polyurethane-carbon black electro-active shape memory nanocomposite for aerospace systems

Arun

Kumar

et al. 2019

Materials Science and Technology

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Carbon black conductive filler material, 2–40% by weight was added to specially designed polyurethane polymer to prepare shape memory polymer nanocomposites. The synthesised polyurethane (PU) has exhibited a high glass transition temperature of 85°C compared to the reported values in published literatures. The polymer was characterised for its chemical, electrical, thermal and mechanical properties. The stiffness, load-bearing capacity and electrical conductivity were observed to improve with increased carbon loading. It was found to be capable of responding to thermal as well as electrical stimuli. The shape recovery efficiency was found to be 94% for thermal and 98% for electrical stimuli which is among the highest for PU reported so far.

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Influence of temperature on the forming limit diagrams of sintered P/M preforms of steel

Chakravarthy

Chakkingal

Venugopal

2008

Materials Science and Engineering: A

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Enhancement of Mechanical Properties of Luffa Fiber/Epoxy Composite Using B₄C

Jino¹,

Pugazhenthi²,

Ashok³

et al. 2017

j. adv. microsc. res.

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Experimental and Monte Carlo simulation studies on percolation behaviour of a shape memory polyurethane carbon black nanocomposite

Arun¹,

Chakravarthy²,

Girish³

et al. 2019

Smart Mater. Struct.

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Electro-active shape memory polymer nanocomposite from polyurethane matrix with carbon black fillers was synthesized and characterised for its electrical properties. The polyurethane matrix possesses high transition temperature, which enables it to be a candidate for high temperature applications. The carbon nanoparticle content was varied with conductivity measured at each instance, and a percolation threshold value of 6% was observed experimentally. The conductivity phenomenon was studied using Monte Carlo simulation approach on a pseudo random model of the system, developed using constrained optimization by linear approximations algorithm in visual C language platform. The probability of three dimensional network formations of carbon particles was evaluated for varying filler loading and percolation threshold of 6.2% was obtained from the model. The conductive networks formed have resulted in multiple electron paths, generating volumetric heating of the system while connected with a known power supply. This joule heating was used as stimuli for activating the shape memory behaviour by passage of electric current. High shape recovery efficiency (>95%) observed with faster recovery time (25 s), along with high transition temperature (85°) can help to qualify the system for space applications.

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Shape Memory Materials

Arun¹,

Chakravarthy²,

Arockiakumar³

et al. 2018

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P. Chakravarthy

High glass-transition polyurethane-carbon black electro-active shape memory nanocomposite for aerospace systems

Influence of temperature on the forming limit diagrams of sintered P/M preforms of steel

Enhancement of Mechanical Properties of Luffa Fiber/Epoxy Composite Using B₄C

Experimental and Monte Carlo simulation studies on percolation behaviour of a shape memory polyurethane carbon black nanocomposite

Shape Memory Materials

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Resources

About

P. Chakravarthy

High glass-transition polyurethane-carbon black electro-active shape memory nanocomposite for aerospace systems

Influence of temperature on the forming limit diagrams of sintered P/M preforms of steel

Enhancement of Mechanical Properties of Luffa Fiber/Epoxy Composite Using B4C

Experimental and Monte Carlo simulation studies on percolation behaviour of a shape memory polyurethane carbon black nanocomposite

Shape Memory Materials

Contact Info

Product

Resources

About

Enhancement of Mechanical Properties of Luffa Fiber/Epoxy Composite Using B₄C