FS3014 Section 4 (Viscoelastic) PDF

Summary

This document details the viscoelastic properties of food materials, specifically exploring rheological characterization, different models used to study these materials (Herschel-Bulkeley and Casson models), and examples like chocolate, using yield stress as a parameter.

Full Transcript

Section 4:
Rheological characterisation of
viscoelastic food materials
FS3014
Macromolecules, Emulsions and Food Structure

Dr Seamus O’Mahony

1
 Classification of Rheology

SOLIDS VISCOELASTIC LIQUIDS
(Elastic) (Viscous)
 Viscoelastic Rheological Behaviour
Many food materials show an element of both viscous (liquid-like) and
elastic (solid-like) character

These types of materials are described as Viscoelastic

Examples: mayonnaise, butter, margarine, chocolate, whipped
cream, fruit purees, concentrated hydrocolloid solutions/dispersions

Scenario 1: Mayonnaise will not easily squeeze out of a tube when
moderate pressure is applied

Scenario 2: Salad dressing will come gushing out of the bottle with
only a slight pressure squeeze

The fundamental common rheological parameter governing both of
these situations is Yield Stress
3
 Viscoelastic Rheological Behaviour
The rheological properties of some different types of viscoelastic
food materials are as follows:
A minimum shear stress, known as the yield stress (to) must be applied to the
food material before flow commences

At an applied shear stress below the yield stress (τo) the food material behaves as
a solid and strains without flow

At an applied shear stress above the yield stress the food material behaves as a
liquid and flows

Therefore, for these food materials, elastic (solid) behaviour and liquid (flow)
behaviour are displayed, but separately: solid below τo; liquid above τo

For Plastic materials (i.e., material that exhibit a yield stress; e.g. butter,
margarine, “weak gels” such as xanthan solutions) subsequent flow can then be
Newtonian or non-Newtonian, depending on the nature of the material
 Viscoelastic Rheological Behaviour
Bingham Plastic
Displays Newtonian flow above the “Yield Value” t = t0 + hplg
t0 = Yield stress
hpl = Plastic viscosity
 Viscoelastic Rheological Behaviour
Examples of 2 Bingham Plastic Fluids
 Viscoelastic Rheological Behaviour
Data Analysis for Bingham Plastic Materials

Herschel-Bulkeley Model
t = t0 + Kgn

t = Shear stress
t0 = Yield stress
K = Consistency index (or viscosity index = hpl)
n = Shear rate index

i.e., based on the Power Law Model with extra term for Yield Stress
 Viscoelastic Rheological Behaviour
Data Analysis for Bingham Plastic Materials

Casson Model (Equation)
t1/2= tCA1/2 + (hCA g)1/2

hCA = Casson viscosity index
tCA = Casson yield stress

For graphing purposes:
Plot g1/2 vs t1/2
If reasonably linear, slope = hCA1/2 and intercept = tCA1/2

Squaring the intercept gives the Casson value (tCA) of Yield Stress
and squaring the slope gives Casson value of plastic viscosity (hCA)
when the material is flowing
 Viscoelastic Rheological Behaviour
Data Analysis for Bingham Plastic Materials
 Viscoelastic Rheological Behaviour
Data Analysis for Bingham Plastic Materials........ based on graph on previous page
 Viscoelastic Rheological Behaviour
Not just Power Law, Herschel-Bulkeley Law and Casson Model!
 Viscoelastic Rheological Behaviour
Data Analysis for
Bingham Plastic
Materials 
Typical Yield Stress Values
1 dyn cm-2 = 100 cP = 100 mPas

13
 Yield Stress – Importance in Chocolate
Enrobing with Chocolate
Yield Stress: Enrobing of Chocolate

https://www.youtube.com/watch?v=E3OEDvDGokA
 Yield Stress – Importance in Chocolate
Reducing Fat Content of Chocolate

Product development involves trying
to mimic the flow properties (Yield
Stress and Plastic Viscosity) of full fat
chocolate in reduced fat chocolate
using emulsifiers (lecithing and PGPR)
Chocolate Rheology: Low Fat Options?
 Creep Testing of Viscoelastic Materials
Creep Testing
In a typical creep experiment, a fixed stress is applied to a material
instantly and the strain is recorded over time (Creep/Retardation).
The stress is then instantly removed and the strain is again recorded
over time (Recovery/Relaxation)....... This approach is often referred to as Creep-Recovery testing

Stress Relaxation Testing
In a typical stress relaxation experiment, a stress is applied to deform
the material to a set strain; the strain is maintained constant and
force, stress or modulus is measured over time.

Both Creep and Stress Relaxation experiments can be carried out
either in compression or in shear....... most commonly done in shear format using a rheometer
 Creep Testing of Ideal Solid Materials
Apply a constant stress.... measure strain

Apply Stress Remove Stress
Creep Testing of Ideal Liquid Materials
Apply a constant stress.... measure strain

Apply Stress Remove Stress
Creep Testing of Viscoelastic Materials

Apply Stress Remove Stress
Creep Testing of Viscoelastic Materials
If a fixed stress is applied to a solid-like sample such as a
biopolymer gel, the strain will gradually increase over time
(creep compliance), and on release of the stress the sample will
only partially recover its original geometry.

This behaviour may be understood in terms of the gradual
rearrangement of the network to accommodate the applied
deformation by dissociation of pre-existing inter-chain junctions
and their replacement by new interactions between different
chain partners.

In other words, the solid-like network is also capable of flowing
like a liquid (i.e., Viscoelastic response).
Creep Testing of Viscoelastic Materials

The recoverable strain, which corresponds to the
initial sharp increase when the stress is applied,
gives a measure of the solid-like (elastic) character
of the sample, and the irrecoverable strain, which
corresponds to the gradual increase in strain (flow)
during the initial creep period, gives a measure of
liquid-like (viscous) character.
Creep-Recovery Curves for Polysaccharides
Polysaccharide gels (e.g., Carrageenan) show almost complete
recovery when the stress is removed, with only a small irrecoverable
strain due to network rearrangement (flow) during the creep period.
Creep-Recovery Curves for Polysaccharides
For solutions of entangled coils (e.g., Guar Gum) the response is
dominated by liquid-like character, with little, if any, recovery (solid-
like response) when the stress is removed.
Creep-Recovery Curves for Polysaccharides
“Weak gel” networks (e.g., Xanthan) although flowing appreciably
during the creep period, still show substantial elastic recovery when
the stress is removed.
 Creep-Recovery Curves for Acid ‘Milk’ Gels
Cow’s Milk Soy Milk Quinoa Milk

Strongest gel as
compliance changed
most with increasing
stress

Creep-recovery curves recorded at 30oC for acidified bovine, soy and quinoa milks. The
curves show the variation of compliance (J) in response to applied stress values ranging from
1.6 to 102.4 Pa (dashed line).
All samples were viscoelastic in rheological properties
Creep-Recovery Curves for Acid ‘Milk’ Gels
 Typical Stress-Relaxation Curves
Typical Stress-Relaxation curves for different types of materials