Ultrasound Based Wet Process in Textile Ventures

Journal of Textile Science & Engineering

ISSN: 2165-8064

Open Access

Opinion - (2022) Volume 12, Issue 3

Ultrasound Based Wet Process in Textile Ventures

Angel R. Hernandez Martinez*
*Correspondence: Angel R. Hernandez Martinez, Center of Applied Physics and Advanced Technology of the (UNAM), Universidad Nacional Autónoma de México, Mexico, Email:
Center of Applied Physics and Advanced Technology of the (UNAM), Universidad Nacional Autónoma de México, Mexico

Received: 02-Mar-2022, Manuscript No. jtese-22-60408; Editor assigned: 04-Mar-2022, Pre QC No. P-60408; Reviewed: 16-Mar-2022, QC No. Q-60408; Revised: 21-Mar-2022, Manuscript No. R-60408; Published: 28-Mar-2022 , DOI: 10.37421/2165-8064.2022.12.476
Citation: Martinez, Angel R. Hernandez. “Ultrasound Based Wet Process in Textile Ventures” J Textile Sci Eng 12 (2022): 476.
Copyright: © 2022 Martinez ARH, This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.


A Ultrasonic generator produces the high recurrence energy for the cycle. The electric variety lies somewhere in the range of 20 and 40 KHz. The electronic vibrations of the generator sent to the ultrasound head by a safeguarded wire and changed over into mechanical vibrations by ceramic piezo ring. The earthenware ring is squeezed into a metal body, which improves the vibration arrives at its most extreme, which lies in the reach.

To place the ultrasound into impact a nearby contact between the sonotrode and the merchandise is important. This is helped by chipping away at out surface, e.g., glass or by squeezing a separate counter instrument to the sonotrode. Consequently, the vibrations are sending to the material to be handled and make inner friction, heat and conceivably handling. The succession of tasks of the plant is constrained by micro-computers. Ultrasound innovation can be credited to different instruments. The impact of Ultrasonic relies upon different variables like radiation pressure, heat, streaming, cavitations, tumult, interface insecurity and erosion, and dissemination and mechanical break.


The components included are expanding enlarging in water, diminishing glass progress temperature of the fiber (enlargement of undefined districts), expanding the fiber/color shower segment coefficient, improving vehicle of the color to the fiber surface by lessening the limit layer, and separating of micelles and high atomic weight totals into uniform scatterings in the color shower.

Expanding enlarging in water

The expanding of both mercerized and un-mercerized cotton filaments with water alone and with ultrasound has been examined. Ultrasound causes huge fiber enlarging contrasted with water alone. Since cotton strands are non-uniform and difficult to gauge, tests were rehashed a few times and the outcomes arrived at the midpoint of.

A few strategies for estimation were utilized to affirm the outcomes. For un mercerized cotton, expanding with water alone ranges from 10% to 20%, yet with ultrasound the reach is from 25% to practically half. For mercerized cotton, enlarging with water alone is just around 3%, yet with ultrasound it is around 35%. The mercerization interaction causes long-lasting enlarging of the cotton fiber of interest here is that ultrasound actually causes extra enlarging. The fiber enlarging is noticed for at minimum an hour after the evacuation of the ultrasound, as long as the fiber stays in water. When eliminated from water and permitted to dry, the fiber gets back to its unique width.

As Dr. G. Mock, R. McCall and D. Clod completed tests. Five distinct tank colors of realized structure were analyzed, the greater part of which had recently been utilized in ultrasound coloring preliminaries. A 5-gpl arrangement of each color was ready and afterward isolated in half to give two examples for each color. One example of each color was treated with 20 kHz ultrasound at 250C for 60 Min; the other example was utilized as a control untreated example. The color tests were estimated with a Honeywell Microtrac Particle Size Analyzer. Ultrasound decreased the normal size of the color particles for every one of the colors tried. The impact went from practically nothing on account of Vat Black 25 to more prominent than 1.75 microns on account of Vat Violet The impact of ultrasound on molecule size is most obvious while looking at the when realistic appropriations drawn by the analyzer. Ultrasound had the best impact on tank colors with bimodal molecule dispersion. After these color tests were treated with ultrasound the enormous particles were totally disposed of. Without ultrasound tank colors might contain particles bigger than 14 microns, however when tank colors are treated with ultrasound the biggest color particles are more modest than 2 microns [1-5].


In the low force application, input power levels are low sufficient that there will never be any adjustment of the condition of the medium. Average models are the non-horrendous testing of materials and estimation of flexible properties of materials. Extreme focus applications, wherein stage changes have more serious impact on the medium, are by and large significant for wet cycles. In most compound responses, response rate is found to increment with power.


  1. .Lofterod, Bjorn, Terje Terjesen, Ingrid Skaaret, Ann-Britt Huse, and Reidun Jahnsen. "Preoperative gait analysis has a substantial effect on orthopedic decision making in children with cerebral palsy: comparison between clinical evaluation and gait analysis in 60 patients.Acta orthopaedica 78 (2007): 74-80.
  2. Google Scholar, Crossref, Indexed at

  3. Simon, Sheldon R. "Quantification of human motion: gait analysis benefits and limitations to its application to clinical problems." J Biomech 37 (2004): 1869-1880.
  4. Google Scholar, Crossref, Indexed at

  5. Scataglini, Sofia, Stijn Verwulgen, Eddy Roosens, Robby Haelterman, and Damien Van Tiggelen. "Measuring Spatiotemporal Parameters on Treadmill Walking Using Wearable Inertial System." Sensors 21 (2021): 4441.
  6. Google Scholar, Crossref, Indexed at

  7. Cimolin, Veronica, and Manuela Galli. "Summary measures for clinical gait analysis: A literature review.Gait & posture 39 (2014): 1005-1010.
  8. Google Scholar, Crossref, Indexed at

  9. Park, Jinse. "Quantitative Analysis of Gait and Balance." Journal of the Korean Neurological Association (2017): 5-9.
  10. Google Scholar, Crossref, Indexed at

Google Scholar citation report
Citations: 672

Journal of Textile Science & Engineering received 672 citations as per Google Scholar report

Journal of Textile Science & Engineering peer review process verified at publons

Indexed In

arrow_upward arrow_upward