On Line Weight and Shrinkage Control of Cotton Knits

NTC Project: S01-PH07 (formerly I01-P07)
Mohamed Abou-iiana, leader; Christopher Pastore,
Claire Beevers (PhilaU), Yasser Gowayed (Auburn)
Recent advances in computer technology have brought
process automation to many areas of the textile industry.
However, knitted fabric structure parameters, such as
courses per unit length, wales per unit length, cover factor,
fabric thickness and weight per unit area, are still measured
manually. This requires large fabric samples and many
testing tools. Moreover, manually counting the courses and
wales per unit length and unraveling the fabric to determine
stitch length are subject to human error and are time consuming.
We developed an on-line system that uses
image analysis during the knitting process
to predict knitted fabric defects
much faster than human experts
and with greater accuracy.
The key to characterizing a knitted structure lies within
its basic element, the single knitted loop. Previously, researchers have shown that the length of a yarn knitted into a
single loop determines such overall fabric qualities as hand,
comfort, weight, extensibility, finished size, cover factor
and most importantly fabric dimensional stability. Therefore, the single knitted loop must be of the correct size and
shape for a given set of fabric performance criteria.
On-line Image Analysis of Knitting
If we can measure the knitted loop on-line, we believe
that image analysis and processing techniques can correlate
on-line size and shape with fabric properties in a matter of
seconds with great accuracy. It might also provide a means
for maintaining the required loop shape to achieve certain
fabric properties. We have now shown that image analysis
of the knitting process has great potential to provide reliable measurements to objectively evaluate of knitted fabric.
Using the principles of image analysis, we developed an
automatic fabric evaluation system, which enables rapid
structure-analysis of knitted fabrics. We can now automatically measure fabric construction parameters by analyzing fabric images captured by a CCD camera and preprocessed by Gaussian filtering and equalization function.
slow compared with that of fabric production and many experts are required, each with their own subjective decisions.
We developed a quality evaluation system to detect and
classify knitted fabric defects, such as hole, fly, needle run
and various barré defects. From an analysis of a wide variety of defect and defect-free fabrics, our system predicted
quality, thus performance, consistent with results obtained
from a panel of expert inspectors (see Graph). In several
cases, our system‘s classifications were better than the expert evaluations.
Conclusions
We developed an on-line computerized system that uses
image analysis during the knitting process to predict knitted
fabric defects much faster than human experts and with
greater accuracy. The results of our on-line computerized
analysis corresponded well with experimental values. Our
system should also be able to identify the type and potential
source of a defect and provide the operator with information about how to correct the problem. It is expected that
the quality evaluation system can be used for automatic online quality control on the knitted machine or as a supplement to objective gradation of knitted fabric.
100
90
80
Performance %
On Line Weight and Shrinkage Control
of Cotton Knits
70
60
50
40
30
20
10
0
Defect
free
Hole
Program
Fly
Needle
run
Experts
Stitch
length
Variation
Thin end Thick end
Contributing Graduate Students: Safinaz Youssef, Suhasini Ram (PhilaU), Ebraheem Shady; Research Associate: James Kaufmann (Auburn).
Industry Interactions: 3 [National Textiles];
Other Interactions: Non-NTC Academic: 1; Government: 2
Project Web Address:
http://fibers.philau.edu/ntc/S01PH07
For Further Information:
1. Textile Institute World Conference, Cairo Egypt, March 2002.
Using our new system we documented changes in knitted fabric structure as a result of different relaxation conditions and characteristics of structural changes in knitted
fabrics during the manufacturing processes. Our image
capturing and analysis system is capable of on-line control
of the spatial characteristics of the knit structures before
and after wet treatments.
Predicting Knitted Fabric Defects
Evaluation of knitted fabric for quality is very important
for determining its commercial value. Many researchers
have worked to automate fabric quality evaluation, but it is
still done mainly by human inspectors who mainly just
point out defects. Moreover, manual inspection is very
National Textile Center Research Briefs –Management Systems Competency: June 2004
NTC Project: S01-PH07 (formerly I01-P07)
Mohamed Abou-Iiana, an Asistant Professor of Textile Engineering at PhiladelphiaU since 1997, earned his Ph.D.
from NC State in knitting engineering
in 1995, a masters from Leicester Polytechnic (ENG) in 1987, and B.Sc. in textile engineering from Alexandria University (Egypt) in 1983. Mohamed spent
about 15 years in the textile industry in
Egypt and USA in knitting, dyeing and
finishing and apparel industries. His
research interests include knitting, online control of knitting machines, mechanical properties of fabrics and
software development for the textile
industry.
I98-P03, S01-AE32, S01-PH07*
abouiianam@philau.edu
(215)-951-2680
http://faculty.philau.edu/abouiianam
Claire Beevers, an Associate Professor
of Textile Design at PhilaU, joined the
faculty in 1985. Claire has a B.Sc. in
textile design from Huddersfield Polytechnic in 1981 and a M.A. in textile/fashion design from Leicester Polytechnic in 1983. Her research interests
include weft knit fabric development,
particularly 3 dimensional shaping for
industrial and technical applications.
SO1-PH07
beeversc@philau.edu
(215)-951 2511
http://faculty.philau.edu/beeversc
Yasser A. Gowayed, a Professor at Auburn joined the faculty in 1992, when
he received a Ph.D. in fiber and polymer science at NC State. He also
earned a M.S. in materials engineering
from the American University (Cairo) in
1989 after an 8-year career in industry
as a structural designer and civil engineer. Yasser's research interests include modeling and analysis of textile
composites, image analysis, geotextiles and re-utilization of solid wastes.
F92-A02, F92-S12, F94-A08, F95-A24*,
I95-A11, F98-A04, I96-A09, F00-PH05, S01-PH07, C02-AE08*
ygowayed@eng.auburn.edu
(334)-844-5496
http://www.eng.auburn.edu/~ygowayed
Christopher M. Pastore, an Associate
Professor of Textile Engineering and
Technology and Director of Research
of the School of Textiles and Materials
Technology at PhilaU, joined the faculty in 1995. Previously he was on the
Textile Materials Science faculty at NC
State and the Materials Engineering
faculty at Drexel Univ. Chris holds a
B.A. and M.S. in mathematics and a
Ph.D. in materials engineering from
Drexel in 1988. His research interests
include modeling of fabric and composite structures.
F92-S12, F92-S09, F98-P01*, S99-PH01*, F00-PH01, F00-PH05*,
S00-PH08, S01-PH07, S03-PH01
pastorec@phila.edu
(215)-951-2683
http://fibers.philau.edu/stmt/cpastore.html
National Textile Center Research Briefs –Management Systems Competency: June 2004