# Introduction

lending in the cotton spinning process has the objective to produce a yarn with acceptable quality and reasonable cost. A good quality blend requires the use of adequate machines, techniques to select bales and knowledge of its characteristics [1]. Blending different types of fibers is a widely practiced method of enhancing the performance and the qualities of a fabric [2]. The blending of different fibers is a standard practice in the spinning industries. The blending is essentially done to enhance the characteristics of resultant fiber mix and to optimize the cost of the raw material. The properties of blended yarns generally depend on the properties of the constituent fibers and their compatibility. Moreover, the proportion of fibers in the blend also plays a significant role. [3]. Natural fibers and their blends with synthetic fibers bear valuable characteristics, so at present, there are various products made of these fibers. It determines that absorbing and discharging moisture, non-irritating, antibacterial, anti-allergic, protection against the sun's harmful Ultra Violet rays and other valuable properties are better than classic yarns. They may be used for clothing, underwear, socks, hygienic, textile products as well as for composites [4]. The blending of different types of fibers is a widely practiced means of not only enhancing the performance but also the aesthetic qualities of textile fabric. Blended yarns made from natural and synthetic fibers have the particular advantage of successfully combining the satisfactory properties of both fiber components, such as the comfort of wear with easy care properties. It also permits an increased variety of products to be made, yielding a stronger marketing advantage [5]. There is a problem in fiber blending technology of selecting specific types of fibers and blend ratios depending on the final product [2]. There are different types of fibers are used to produce blended yarn. Such as Cotton-Viscose, Cotton-Modal, Cotton-Polyester. The degree of orientation of regenerated cellulose fibers depends on stretching during spinning [6].


# II. Material & methods

Cotton is the common blending component used here. Variable elements used here with cotton were viscose and modal fiber. The fiber parameters were tested in AFIS & HVI machine in a standard testing condition (Temperature 20 0 ±2 0 C & Relative Humidity 65±2 percent) [7]. Fiber properties and country of origin shown in table 1. Here, Draw frame blending was applied. Sliver blending gives excellent blending evenness along the length of the product [8].

III. The strength of viscose fiber is lower than modal fiber. It creates short fiber which leads to more unevenness in cotton/viscose blend yarn. As the strength of the modal fiber is same as cotton fiber, so unevenness found lower in cotton /modal blend yarn. The short fiber content in different stages is given in fig. 2 Fig. 2  Modal fiber strength is higher than viscose, so cotton /modal blended yarn showed greater strength than cotton /viscose blended yarn. 


# Result and Discussion


# Conclusion

The results of this work reveal that cotton/modal blended yarn shows better properties than cotton/viscose blended yarn. Though viscose and modal both are regenerated cellulosic fiber, the strength of viscose fiber is lower than modal due to higher molecular weight of modal. When viscose blends with cotton, it creates short fibers and neps during the spinning process. Apart from these, the movement of viscose fiber during drafting is not as much controllable as in case of modal fiber. For the above-mentioned reasons, the cotton/modal blended yarn quality is better than cotton/viscose blended yarn.  Investigation of friction properties of yarns from natural fibers. Mechanics, 75 (1), 73-77.

Viscose creates more short fibers while processing, so hairiness of cotton/viscose blended yarn is more than cotton/modal blended yarn. Short fiber content of different stages is showed in fig. 2 
1![Fig. 1: Unevenness (U% & CV %) of cotton /viscose & cotton /modal blended yarn](image-2.png "Fig. 1 :")
456![Fig. 4: AFIS neps content per gram at the different stage of blending](image-3.png "Fig. 4 :Fig. 5 :Fig. 6 :")
7![Fig. 7: Hairiness comparison of cotton /viscose and cotton /modal blended yarn](image-4.png "Fig. 7 :")
![to Analyze the Optimum Characteristics of Cotton/Modal & Cotton/Viscose Blended Yarn](image-5.png "")
4![Svetnickien?, V., ?iukas, R., & ?iukas, R. (2009).](image-6.png "Hairiness 4 .")
1PropertiesCottonViscoseModalFineness4.30 ?g/inch4.31 ?g/inch4.31?g/inchUpper quartile length(UQL)28 mm38 mm38 mmStrength28.83 gm/tex15gm/tex30 gm/texCountry of originMali & SenegalIndonesiaThailand
A Potential Approach to Analyze the Optimum Characteristics of Cotton/Modal & Cotton/ViscoseBlended YarnYear 201810U% & CV%J ( ) Volume XVIII Issue II Version I11.15 14.26 fiber and neps during processing which creates more 10.55 13.48 0 2 6 10 12 14 16 IPI comparison of cotton /viscose and cotton /modal blended yarn U% CV% Thick place, thin place, and neps found higher imperfection in cotton/viscose blended yarn than 8 in cotton/viscose blended yarn. As the strength of cotton/modal blended yarn. Neps generation 4 viscose fiber is less than modal so it creates more short percentage in different stages shown in fig. 7Global Journal of Researches in Engineering7 8 9 10 11 1210.7 11.210.8 10.2 AFIS short fiber content (SFC)9.710.48.3 8.9Cotton/Modal-50/50 Cotton/Viscose-50/5065Drawframe-1Drawframe-2Drawframe-3Simplex
			© 2018 Global Journals
		
		
			

				


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