Studies on deformation characteristics of albumen belkozin membranes using hysteresis loops technique/Baltymines belkozino pleveles apvalkalo deformaciniu savybiu tyrimas panaudojant histerezes kilpas.
Paulauskas, L. ; Kairaitis, R. ; Paulauskas, S. 等
1. Introduction
Packaging materials, which directly contact the food products must
possess chemical resistivity, have certain physical, chemical,
mechanical and technological properties, meet hygiene requirements and
assure high automation level of the packaging process [1-5].
It is quite common that smoked, boiled and liver sausages, also
curd, diet curd, curd for children, sour-cream, ice-cream mass and
similar consistence products are being packed into round bar-shaped
packs produced from the sleeve filled-in with the product. During the
filling the sleeve is being portioned and divided into separate round
bar-shaped packs by metal clips prior to separating from the sleeve by
cutting [5]. The sleeve itself can be made of protein belkozin, polymer
povidene, polyethylene and other materials, which meet hygiene,
technological and technical requirements and are suitable for the
specific product type [2-4].
The protein belkozin casings are used quite often for filling of
boiled and smoked sausage meat. The main part of protein film is a
protein collagen, which has fibred structure with hard enough separate
fibers. These fibers when twisted make up the sieve of quite high
mechanical strength. Protein casings during the sausage manufacture are
affected by high temperature, pressure and other factors, which
obviously have influence on their properties. These factors must be
taken into account when choosing the optimal operation parameters. The
properties of casings are very much dependant on soaking medium and the
soaking duration, therefore these parameters should be set very
carefully in order to produce an elastic and nonbreakable casing.
Relaxation tests at load levels below ultimate tensile strength can
provide information about deformation properties of the protein belkozin
casings used in production of cooked and smoked sausages. Deformation
properties are very important especially in case of automatic filling
the casings with minced meat where the casings are exposed to several
expansion cycles performed at high speed. As a result the casings brake
quite often because of limited ability to withstand multicycle loads
thus causing various problems related to stability of production
process, productivity, etc.
The aim of this study is to determine experimentally deformation
properties of casing material at multiple load-unload stress performed
at constant speed in order to simulate real working conditions of the
casing during the automatic sausage production. Recorded stress-strain
curves of the casing material appear in the shape of hysteresis loops
and represent the performance of protein belkozin casings during the
automatic filling it with the sausage mass. The results presented in
this article can be considered as an extension of previous research
[1-3].
2. Experimental research methodology
Mechanical properties of belkozin protein film coatings depend on
many factors: sample cutting direction, film type and diameter,
plasticizing media and others. In this paper we have limited the
research, focusing mainly on general properties and their dependence on
basic film parameters: type, sample cutting direction and the shell
diameter. Mechanical properties of belkozin were investigated using 65
mm film sleeve, type OP. Examination was carried out on longitudinally
and transversally cut specimen.
Specimens were cut by using special equipment to ensure that their
edges are perfectly smooth. Specimen width was 10 mm and working
length--100 mm.
Prior to tests the samples have passed 48 h conditioning in the
atmosphere at normal humidity w = 65 [+ or -] 2% and temperature T = 293
[+ or -] 2 K.
Similarly to [1] during tests the load was applied at a constant 30
mm/min speed until the set load value is reached. It is considered that
the load value applied to a specimen is the one, from which starts the
unloading. After the application of 2-6 cyclic load cycles, the load has
been increased up to the tensile strength. During the tests loading
duration was set to be 120 s, unloading--360 s. Loading force has being
increased from 10 N to 40 N by increments.
Film deformation research has been carried out by using universal
relaxograph, a special device UM-131 used to electronically measure
mechanical parameters also a linear electronic recorder EZ-11.
3. Study of albumen belkozin membrane deformation dynamics by using
hysteresis loops
Some researchers claim [6-8] that hysteresis stress-strain loops
can be both informative and helpful when investigating complex
deformation processes of the materials. By registering strain-stress
curves caused by the applied load during its increase and deduction at
constant speed a number of important physical and mechanical parameters
can be obtained: plasticity of the material, its hardening phenomenon,
reverse deformation dynamics, etc. Limited stretch of the material is
being performed to a certain deformation level below.
During the first stage of research aimed at identifying deformation
parameters similar to those occurring during the industrial
exploitation, the cyclic load was set within the 75-80% of the tensile
strength. Each specimen was subjected to a 3 cycle load test with the
above load applied, which was afterwards followed by the load to cause
fracture. Typically such test produces loading-unloading curve shown in
Fig. 1.
An experiment confirmed the earlier obtained belkozin deformation
characteristics [1]:
a) during each load cycle belkozin becomes more stiff, which is
reflected by an increasing angle [alpha].
b) each load cycle increases an offset strain.
In addition is has been established that a specimen becomes more
strong after it has been affected by cyclic load. The application of 3
loading-unloading cycles with the 75% load of ultimate tensile strength
(UTS) has led to an increase of UTS value from 54 N to 58 N, or by 7,4%.
[FIGURE 1 OMITTED]
Film strengthening phenomenon was observed also during the
experiments where variable number of cyclic loads and variable load
values have been applied. Please see the test results in Figs. 2 and 3.
It can be seen that in the range from 1 to 5 load cycles the
strength of the film is increasing. Further increase of the number of
cycles is not followed by the increase in film strength, contrary even
some decrease can be observed, especially when higher loads are applied.
Supposedly, it happens because the material properties are subject to 2
parallel processes within the material structure, which follow the
cyclic load: a) initially observed increasing orientation of the
belkozin molecules after the 4-th cycle becomes less displayed; b)
material fatigue, which becomes visible with the increase in number of
load cycles.
Strengthening process of the film is also subject to the value of
cyclic load. Maximum strengthening effect was achieved at the load range
from 58 to 62% of the UTS. Approximately 10-11% increase in film
strength was registered in specimen exposed to 4-5 cyclic loads at
58-62% of UTS performed at constant speed. This combination of
parameters seems to be optimal for this type of film.
Strain at fracture similarly to the film strength is also dependant
on a number of cyclic loads as well as the load value. Curves of the
graphs in Figs. 2 and 3 confirm that cyclic loading up to 4-5 times
result in increase of offset strain at fracture, while further increase
of load number causes adverse effect. Nevertheless, in all the cases a
specimen not exposed to cyclic load have produced lower strain at
fracture values compared to those exposed to cyclic load. Max observed
difference was 15-20%.
4. Changes in belkozin structure at stretch
A number of factors should be taken into account when analyzing
mechanical properties of belkozin: collagen fiber structure and
orientation, interaction between structural elements, influence of
inter-fiber filler material on the properties of structural elements and
their changes.
Numerous researchers underline close relationship between collagen
properties (e.g. strength, ductility, etc.) and the material structure
[7-10]. Belkozin is a fibrous material with collagen fibers oriented
with a certain angle against its longitudinal axis. As a result the
fibers inside the longitudinally and transversally cut specimen also
appear to be oriented with a certain angle towards the stretch load
axis. Belkozin's fiber structure has similarity with mesh-work and
its' fiber orientation generally is quite complex. Two major types
of bonds occur between the structure elements: interlace of elements and
friction bonds.
Some indirect information about the structure of the material being
tested and the existing inside links can be obtained from hysteresis
loops and their shape. In general the shape of hysteresis loop can be
either convex, concave or linear. Hysteresis loop shape of belkozin
specimen at stretch presented in Fig. 1 suggests that unlikely there do
exist any adhesive bonds inside the material structure.
This might be one of the reasons why stiffness and strength
properties of specimen are increasing as a result of exposure to cyclic
load. Another reason could also be additional bonds between the fibers
as described by Mikhailov A.N. [11]. According to him the collagen being
a soft capillaries based hydrophilic sorbent tends to loose water as a
result of mechanical cyclic loads. Loss of water from capillaries makes
the structure drier with more bonds between the fibers, which otherwise
would be interlinked via water molecules and virtually would not be
active.
Changes of instantaneous offset strain, which appear inside the
belkozin structure, can be explained through the loss of partial fiber
bonds caused by the applied tensile load. As noted by Pakshver A.B. [7]
this has some similarity with the processes in textile materials. Still,
the role of collagen fibers and their properties should not be excluded
and diminished. Research carried out using different types of collagen
fibers has demonstrated the existence of instant offset strain.
It's very likely that under the influence of
conditional-instantaneous stretch stress of specimen the irreversible
structural changes of the fibers is followed by the deformation of
collagen fibers themselves.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
5. Conclusions
1. Research of belkozin deformation properties at cyclic
loading-unloading, performed at constant speed has been carried out. The
registered hysteresis stress-strain loops indicate about the increasing
strength of belkozin structure as a result of exposure to cyclic stretch
loads. Breaking strength and strain at fracture parameters have been
investigated and their dependence on number of load cycles and load
value established. At optimal load value, equal to 58-62% of ultimate
tensile strength and 4 stretch load cycles a maximum of 10-11% increase
in braking strength and 15-20% increase of strain at fracture has been
achieved.
2. Experiments have demonstrated that deformation properties of
belkozin are subject to film orientation and are different in
longitudinal and transversal axis. Belkozin features nonpersistent
offset strain, which is dependant on cyclic load, where maximum
reduction is being registered during the first load cycle with further
declining reduction related to following cycles. Exposure to multiple
loads causes permanent increase in film stiffness and the related
reduction of ductility with every new load cycle applied.
Received February 15, 2011
Accepted November 30, 2011
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L. Paulauskas *, R. Kairaitis **, S. Paulauskas ***, E. Milcius
****
* Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]
** Lithuanian Academy of Physical Education, Sporto 6, 44221
Kaunas, Lithuania, E-mail:
[email protected]
*** Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]
**** Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]