As we already mentioned in connection with the
sedimentation value, the quality of the wheat gluten is extremely important.
Since it is a genetic attribute, it is given great attention in the breeding of
new varieties. The quality of the gluten is the basis for assigning the wheat varieties
to quality groups. For investigating the dough properties dependent on the gluten
it has become usual to employ methods that show water absorption and mixing
stability and also record the extensibility of the dough. The changes to the dough
during fermentation and baking can also be detected with special instruments. Suitable
devices for this purpose are the Maturograph and the Oven Rise Recorder.
1. Determining
Water Absorption and the Mixing Behaviour of Wheat Doughs with the Farinograph
In the Farinograph (Fig. 45) a dough is prepared under
standardized conditions from 50 or 300 g of flour, depending on the size of the
mixer. While the dough is being made up, its resistance to the mixing paddles
is measured and recorded continuously. In order to achieve uniform dough properties
it is first necessary to measure the water absorption of the dough. To do this,
water is added to the flour, which has a moisture content of 14%, from a
burette until the dough reaches a consistency of 500
FU14. This amount of water
is a measure of the water absorption of the flour, since a consistency of 500
FU corresponds to the average firmness of a dough. It is often necessary to
make several attempts to determine the amount of water needed, as it is rarely
possible to add the liquid to the mixer so quickly the first time that no dough
softening occurs.
Fig. 45: Farinograph - E (source: Brabender OHG) |
Once the amount of water has been determined, another
dough is made from the same flour by adding all the necessary water at once.
This dough is then mixed for 12 min. On the graph paper or the VDU15 there
appears a mixing curve from which it is possible to read off the development
time, the stability and the softening of the dough.
These Farinograph data can be used for preparing the
dough. The water absorption – largely dependent on the quality of the gluten –
indicates the dough yield; the doughdevelopment time permits conclusions on the
speed of swelling; the fall in consistency (degree of softening) shows whether
the flour is strong (slight fall) or weak. The Farinogram curves are characteristic
of the gluten properties of a flour.
Farinogram curves with a broad band (bandwidth) and
only a slight fall over the mixing time indicate elastic doughs that do not
become weaker even when exposed to intensive mechanical stress. These flours
are most suitable for bread rolls and toast slices. In flours with very strong
gluten the consistency may even be found to increase during mixing. Subsequent
swelling of the gluten causes the dough to become firmer. Narrow curves with very
obvious dough softening result from weak flours (flours with weak gluten),
which should preferably be used for making biscuits. Testing of wheat flours
with the Farinograph conforms to ICC Standard No. 115/1. Since there are other
methods of evaluating the curves (e.g. according to Brabender), the method used
should be stated. Simple adaptation of the equipment and connection to a
personal computer with the appropriate software makes it possible to evaluate
and store the measurements electronically. With the addition of a printer, the
software can produce a complete report on the results if required. The water absorption
for certain standard baking tests is also determined in the Farinograph. For
the baking test for white pan bread the measurement used should be 350 FU, for
the Rapid Mix Test and the wholemeal wheat baking test it should be 500 FU. The
Farinograph can also be used for standardizing rye doughs. The dough
consistency for the sour dough baking test with rye flours should be 300 FU.
The dough for measuring stretching properties with the Extensograph is also
prepared in the Farinograph.
2. Determining
the Stretching Properties of Wheat Doughs with the Extensograph
The Extensograph (Fig. 46) has proved to be a useful
instrument for determining the stretching properties of wheat flour doughs. To
do this a dough is made up of flour, water and salt under standard conditions
in the Farinograph and rolled out in the rounder and shaping unit. After 45, 90
and 135 min the piece of dough held by clips is pulled by the stretching hook until
it ruptures.
Fig. 46: Extensograph (source: Brabender OHG) |
The force exerted during stretching and the length
of the extension are recorded on graph paper. Both resistance to extension,
measured as the force required for stretching, and extensibility (stretching
length to rupture) are important variables for assessing wheat flour doughs.
The curves of an Extensogram give a clear indication of the results to be
expected when the flour tested is baked. If the resistance to extension is low,
i.e. the curve is rather flat, the dough has weak characteristics and the baked
volume will be small. If the curve of the Extensogram rises steeply and is
quite pointed at the top, the dough may be assumed to have short characteristics;
such doughs are also said to be "bucky". In this case it is difficult
to influence the structure of the dough; the gas formed
by the yeast is not sufficient to achieve the necessary leavening. The best Extensograms
for making bread and rolls are those with a well-balanced curve. The following
curve (Fig. 47) shows an example of a flour that is well suited for the
mechanical production of bread.
Fig. 47: Extensogram with a "balanced" curve (source: Brabender OHG) |
The Extensograph offers a simple method of testing
the effect of additives on the properties of the gluten. For example, the
amounts of ascorbic acid to be added to improve wheat flour should first be
determined in the Extensograph. Too much ascorbic acid results in Extensogram
curves characterized by high resistance to extension and rapid rupture of the
dough. All substances acting on the gluten (cysteine, cystine, proteinases
etc.) can be tested in this way for their effects on the dough made from a
flour.
Evaluation of the curve drawn on the graph paper by
the plotting device yields a number of measurements. First, the resistance of
the dough to extension and its extensibility should be established. Then the
area below the curve can be determined as an indicator of fermentation tolerance.
The area is stated in cm2 and referred to as energy. ICC Standard 114
does not provide either for information on the energy or for calculation of the
Ratio Number, but this data should always be used for rating flours. The Ratio
Number is calculated by dividing resistance by extensibility. The different measuring
units are disregarded. High Ratio Numbers indicate a gluten with short dough
properties and baked products with a low volume. Flours with Ratio Numbers below
2 are not suitable for making bread rolls.
3. Determining
the Extensibility of Wheat Doughs with the Alveograph
The Alveograph (Fig. 48) is used chiefly in the Mediterranean
countries, parts of South America and the former French colonies in Africa for
testing the extensibility of dough. The principle is based on an extension test
in which a disc of dough in a holder is blown up into a bubble (alveolus). The
aim is to investigate the stretching properties of the dough up to the point
where the bubble bursts. The process of extension and the volume achieved are
recorded as a curve from which it is possible to read off the baking properties
of the wheat flour. Testing of flour with the Alveograph is described in ICC
Standard No. 121.
Fig. 48: Alveograph and Consistograph (source: Mühlenchemie GmbH, Ahrensburg) |
4. Mixograph
for Determining the Water Absorption and Mixing Times of Wheat Doughs
In the USA the Mixograph (Fig. 49) is often used
for testing the baking properties of wheat flours. In the newly developed
computerized Mixograph it is possible to determine the water absorption of
flours with as little as 10 g of flour.
Fig. 49 Mixograph with mechanical plotting of the measurements (source: Oregon State University ) |
The Mixograph curve also reveals the mixing tolerance
(MT) of the dough. The dough development time and a fall in the viscosity of
the dough can be read off the curve with certainty. As with the Farinograph,
the extent of the "tail" of the curve indicates the quality of the flour.
5. Method
for Testing the Aggregation Behaviour of Wheat Gluten for the Production of
Wafer Batters
In the gluten aggregation test (Fig. 50) a slurry of
wheat flour is tested for its suitability for making flat wafers. The
instrument measures the electric current consumed by the mixer. For the test a
thin wheat flour/water suspension is beaten at high speed. The gluten thus formed
increases the shear forces, and this in turn alters the power consumption of
the mixer. The aggregation time, recognizable by the time of greatest power
consumption, and the aggregation area described by the curve are used in the evaluation,
as are the maximum, mean power consumption and the rise in temperature.
Fig. 50: Equipment for performing the gluten
aggregation test (source: Brabender OHG) |
Aggregation times up to 80 s indicate soft gluten
structures that go hand in hand with high water absorption and average baking potential.
Samples with a higher protein content and corresponding gluten structure formation
have aggregation times of about 100 - 250 s. In this case very good baking properties
can generally be expected. The flour quality is less suitable if the
aggregation times are longer than 300 s.
Note :
14 FU = Farinograph Units; also referred
to as Brabender Units (BU)
15 VDU = Visual display unit
16 EU = Extensograph Units; also
referred to as Brabender Units (BU)
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