Article Type: Research Article Article Citation: Rajesh C M, and
Bharath Kumar G. (2021). CHROME FREE RAPID GLOVE LEATHER MANUFACTURE. International
Journal of Research -GRANTHAALAYAH, 9(2), 172-180. https://doi.org/10.29121/granthaalayah.v9.i2.2021.3497 Received Date: 07 January 2021 Accepted Date: 27 February 2021 Keywords: Chrome Free Glove Leather Acrylic In the current study, we use chrome free tanning process for the production of glove leather and to achieve the required properties without any compromising the quality. To develop a suitable post tanning system for making glove with good softness, run and strength properties. Glove leather predominantly made using chrome tanning system. Conventionally glove leather is done by long liming and ageing in pickling for better fibre splitting in order to achieve the run property. Production Time is very high due to long liming and ageing in pickling. Production cost can significantly reduce if the processing time for making glove is reduced. Acrylic followed by Glutaraldehyde combination tanning system adopted for chrome free tanning option. Long liming and ageing in pickle will be replaced with rapid fibre splitting process.
1. INTRODUCTIONA glove
literally means “a cover” for hand with a sheath for each finger, but it is
more than that. A good glove has to be a defense against cold and water, should
maintain the body temperature and it should also leave the hand mobile enough
to drive a vehicle, press a bomb button at the exact second, to grasp some
heavy object lying underneath or to operate a machine etc. Leather is unique
and ubiquitous, as old as man and yet modern. Leather contributes to a
country’s wealth. Leather is an international commodity and in spite of the
severe competition from synthetics, the demand for the leather in the world
shows a rising trend. So far, these substitutes have remained mainly as
supplements. The inherent superiority of leather, rising population, higher
incomes and leisure, new uses for leather, rapid changes in fashion snobbery
and greater use of resources have all contributed to this continued demand for
leather. The
demand for leatherwear has now been growing greater and greater. There is every
indication that it will continue to do so for some more time. It is now an
accepted fashion that leather is perfect material for all seasons and all
moods. As atop fashion material, leather is used in the production of suits,
coats, gloves, hats, ties etc. and it has now become a luxury material. The
suppleness and wearability of glove leather in every color have captured the
hearts of style conscious people everywhere. This raised demand for glove
leather. Chromium
has been used as the primary tannage for many leathers for over 100 years. In
the early days the tanning form, Cr (III), was produced from Cr (VI) in the
form of Dichromate by reduction of the chrome in the tanning bath by sugars at
low pH. When basic chrome sulfate was introduced as a
product ready to be used for tanning, tanneries changed to the use of these
products either as an aqueous solution or as a dry product. Environmental
concerns about the effects of Cr (VI) and other heavy metals resulted in strict
guidelines as to the amount of soluble chrome that could be discharged in a
tannery waste stream and disposal of waste leather from shavings, trimmings and
buffing dust was limited to contained landfills. There is no doubt that Cr (VI)
compounds are both acutely and chronically toxic. The dose threshold effect for
this element has not yet been determined accurately enough to allow regulations
to be defined. However, some risks assessment analyses are currently being
undertaken. Cr (III) is less toxic than some other elements (Hg, Cd, Pb, Ni,
Zn) to mammalian and aquatic organism. Probably due to the low solubility of
this elements in its trivalent form. Compared to Cr (VI), the toxicity of Cr
(III) is insignificant. Hexavalent Chromium has been proven to carcinogenic and
causes damage to skin. Mucous membrane, respiratory tract, Kidney, etc. It has
also been shown that there are some possibilities for the formation of chromium
(VI) during processing conditions (IS-2490/1985) Recent reports suggest that
higher levels and under certain ligand environments chromium (III) also toxic.
The Problem is aggregated by the fact that the currently practiced chrome
tanning procedures lead to an uptake of only 60-65o of the chrome offered by
leather and hence substantial amount of chrome is discharged into the
effluents. Even, so
the possibility of oxolation of chrome in the
landfill to Cr (VI) with leaching into the environment has been a concern to
Environmental Protection Agencies (EPA). However, the disposal of leather from
worn-out shoes, garments, Glove, Upholstery and the possibilities of ingestion
of chrome tanned leather by children has been addressed only recently. 2.
MATERIALS AND METHODS
2.1. STANDARDISATION OF TANNING SYSTEMWet salted sheep skins of uniform size and
weight were taken and processed into chrome free tanning system using Acrylic
followed by glutaraldehyde tanning system. The control process for gloving and
the process developed with alternate tanning system are shown table, three wet
slated skins (processed as mentioned in Table 2.1) of 5 sq. ft (average) were
used for the experiments. Each wet salted skin was used for each experimental trial.
2.1.1. SELECTION/STANDARTISATION OF POST TANNING SYSTEM Wet salted sheepskins of uniform size and
weight were taken and processed into Chrome free tanning using process shown in
Table 2.1. The post tanning trials was carried out to select suitable fatliquors and retanning agents
to obtain glove leather with high run, strength and softness properties. 2.1.2. SELECTION OF SUITABLE FATLIQUOR Six fatliquors of
different bases were screened for glove leather manufacture. The chosen Fatliquor and their base are shown. Two experimental trials
varying the combination of fatliquors have been
carried out. The experimental trials on Fatliquor are
shown. Fatliquor screened for experiment on glove leather manufacture
2.2. PHYSICAL TESTING AND HAND EVALUATION OF LEATHERSamples
for various physical tests from experiments and control crust leathers were
obtained as per IUP methods (IUP2 2000). Specimens were conditioned at 80 ± 4ºC
and 65 ± 2% R.H. over a period of 48 hrs. Physical properties such as tensile
strength, tear strength and % elongation at break were examined as per the
standard procedures (IUP6 2000, IUP8 2000). Crust leathers were assessed for
softness, fluffiness, grain smoothness and general appearance by hand and
visual examination. Experienced tanners rated the leathers on a scale of 1-10
points for each functional property, where high points indicate better
property. 2.2.1. RUN MEASUREMENT Run is
measured in the following manner. The leather is first stretched lengthwise. In
this condition breath wise length of the leather was measured. It was taken as
initial length. Then the leather was stretched in breadthwise direction and the
stretched breath wise length was found. Difference between the stretched and
initial length is a measure of “Run”. Similarly, for determining the run in the
lengthwise direction, the leather was stretched first in the breath wise
direction. The length was measured lengthwise (initial length). Then the
leather was stretched in the lengthwise direction. The length of the leather in
the stretched condition is measured. Difference of the lengths is a measure of
“Run”. Run
measurements in the case of quarter pieces shown in Figure 2.7 is
carried(stretched) at line (perpendicular to backbone) 30% of distance L from
the centre point A. Similar methodology is adopted
for run measurement of all quarter pieces. In the case of half and full pieces
run measurements were made at centre position
(perpendicular to the backbone) of the total length of the backbone. 2.2.2. SOFTNESS Softness of the leather was measured using
ST300 Digital leather softness tester. The ST300 D is a means of determining
the softness of leather without defacing the hide or skin, as it does not
require samples to be cut from the leather prior to testing. But the
experimental and control crust leathers were conditioned at 80± 4ºF and 65±2%
R.H. over a period of 48 hrs. The softness of the experimental sample was noted
directly after fixing it to the ST300 Digital leather softness tester. This
device has now been adopted as the industry standard by IULTCS (IUP 36). 2.2.3. STRENGTH MEASUREMENT 2.2.3.1. TENSILE STRENGTH & ELONGATION AT BREAK Tensile
strength is the force (kg) per unit area of the cross section (sq.cm) required
to cause the rupture of the specimen. Dumbbell shaped specimen, of required
shape and size are cut both at the parallel and the perpendicular direction of the
back bone of experimental and control crust leathers were obtained as per
IULTCS methods (IUP 6) and conditioned at 80± 4ºF and 65±2% R.H. over a period
of 48 hrs. Width and thickness of the specimen, at not less than 3 places are
measured and the average value is noted. Set the jaws of the tensile tester
apart for each sample respectively. Clamp the test specimen in the jaws and run
the machine at the rate of 100 ± 2 mm/min until the specimen breaks. Note the
distance between the jaws when rupture of the test specimen occurred. 2.2.3.2. TEAR STRENGTH Tear
strength is the load (kg) required to tear the leather beyond the cut made
perpendicular to its surface, expressed per unit thickness. Specimen of
required shape and size are cut both at the parallel and the perpendicular
direction of the back bone of experimental and control crust leathers were
obtained as per IULTCS methods (IUP 8) and conditioned at 80± 4ºF and 65±2%
R.H. over a period of 48 hrs. Thickness of the specimen is noted. Insert the
slot of the specimen into the test piece holder fixed to the tensile tester.
Run the tester at the rate of 100 ± 2 mm/min until the specimen is torn apart. 2.2.3.3. GRAIN BURST LOAD AND DISTENSION (LASTOMETER TEST) Circular
leather pieces (44.5 mm) from the experimental and control crust leathers were
obtained as per IULTCS methods (IUP 12) and conditioned at 80± 4ºF and 65±2%
R.H. over a period of 48 hrs. Clamp the test specimen tightly in the lastometer and force the plunger at a rate of 0.20 ± 0.05
mm/second. When the burst appears note down the force and distention 3. RESULTS AND DISCUSSIONS3.1. EFFECT OF UREA TREATMENTThe
experimental trials have been conducted using 3% urea treatment before tanning.
The tear strength, softness is good. From the literature table it is observed
that usage of 3% urea in pretanning results in
maximum run property around 35%, with further increase in urea the %run is
found to decrease. Urea is a well-known protein secondary structure
destabilizer, beyond a certain concentration they may affect the structure of
the collagen matrix significantly because of rupturing protein, which may
result in lowering of run. But in our experiments, it Shows better results
which had given 35% and 20% run. 3.2. EFFECT OF FATLIQUORS ON GLOVING PROPERTIESSix
different bases of fatliquor have been screened.
Since fish oil is known to posses’ very good lubricating ability, a fatliquor based on fish oil is very essential for glove
leather. Hence, sulfited fish oil fatliquor
(Sfo) has been offered for all experimental trails.
Trials have been carried out with varying the combination of other five fatliquors as mentioned. The run, softness, visual
assessment data for leather processed using different combination of fatliquor is shown Control
Experiment 1
Experiment 2
3.3. INTEGRATION OF BEST TANNING SYSTEM ALTERNATE TO THE CHROME AND POST-TANNING SYSTEMS FOR GLOVE LEATHER Experimental trials have been carried out by
integrating the treatment of 4% urea treatment before tanning along with the 2%
of acrylic and GT-50 at Tanning and best post tanning practices i.e., usage of
4 fatliquors 4% amount each and FB-6 syntans for retanning. The run and other properties of the leathers are
given in the table it is clear that the urea treatment has helped to improve
the run property of glove to the levels equivalent to run of leathers. Post tanning process Control
Experiment 1
Experiment 2
Table 3.1: Strength measurements of glove leathers
4.
CONCLUSIONS AND RECOMMENDATIONS
The chrome free glove leather produces lesser effluent discharge when compared to conventional process. Lecithin based fat liquor is found to improve the softness and run property of glove leather, synthetic fat liquor is found to improve the tear strength property .4% fat liquor each of LP-16, SX-20, SX-25 has been found to be the better combination of fat liquors for good gloving properties. Syntans of 2% offer of DLE and FB-6 have been found to be the optimum amounts. Ageing after pickling have been found to enhance the run property of the glove leathers. 3% Urea pretreatment before glutaraldehyde tanning has been found to be effective which result in glove leather with superior run and strength property, integration of pretreatment of skin with urea followed by glutaraldehyde tanning and post tanning with optimized post tanning practices have resulted in better glove leathers compared to the conventional process. SOURCES OF FUNDINGThis research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors. CONFLICT OF INTERESTThe author have declared that no competing interests exist. ACKNOWLEDGMENTCSIR-CLRI
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