Abstract
This paper parades the effectiveness of conductive yarn resistor instead of carbon resistor by verifying the Kirchhoff’s voltage (KVL) & current (KCL) law. This research work enlightens about the sustainability of e-textiles on account of presenting characteristics of this conductive yarn resistor. Resistor is one of the most useful materials in the electrical laboratories. Generally resistor is made by carbon. Using carbon resistor is pernicious for our environment, society & cost. It is known that sustainability is the concerned area at present. Sustainable e-textile is one of the major need in material science .This quest indicates that point to boggle sustainable e-textile by inventing conductive yarn resistor verifying with most orthodox theory of Kirchhoff’s voltage & current laws. KVL and KCL are the most prominent theory in electrical science. Summation of KVL and KCL will be zero in any closed loop in this theory. The summation of KVL is also zero here and summation of KCL is also zero here. It can justify Kirchoff’s KVL & KCL theory.
Highlights
It is perceived that conductive yarn is the premier ingredient of e-textiles or smart textiles
This study proves that using conductive yarn resistor is better than carbon resistor
Conductive yarn resistor is more flexible than carbon resistor, it is helpful for using electrical laboratories
Summary
It is perceived that conductive yarn is the premier ingredient of e-textiles or smart textiles. On the other hand resistor is that element which resists the current flow. Conductive fabric which can be recognized as application of smart textiles. The resistance of jute fabrics with variation of different gauge length was analyzed [3]. It was observed that decay of electrical conductivity of wool textiles. It was explained that decay of electrical conductivity by in situ oxidization of poly-pyroole with giving stress [1, 4]. Silver nanoparticle preparation is very important to generate the conductive yarn resistor [5]. PET conductive yarn were produced from silver and copper nanoparticles. The surface morphology of silver and copper nanoparticles based conductive yarn was investigated there.
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