Chopin alveograph


The Chopin Alveograph is an empirical tool for wheat flour quality measurement. It measures the properties of the dough produced from the flour, by inflating a bubble in a thin sheet of the dough until it bursts. This process is supposed to simulate the natural bubble growth during the fermentation and in the early stages of baking. An analysis of the recorded graph of pressure vs. bubble volume yields about ten values that characterize the suitability of the flour for different uses. As of the 2020s, the device is manufactured by Chopin Technologies. A similar device for bubble inflation, D/R Dough Inflation System, is made by Stable Micro Systems.

History

The idea of wheat grain classification by using a bubble made of dough dates back to 1905, when a Hungarian, Jenö von Hankoczy, created a "gluten tester". The tester measured only the maximum expansion of the bubble before bursting and, as other early devices, had no temperature control.
Developed independently in the late 1920s in France by, the Chopin Alveograph performs the alveographic test that enables to measure the tenacity, extensibility, and elasticity of a dough. This measurement, known as dough strength, is considered as a good index of the baking quality of baking flours.
The original "extensimeter" design by Chopin was created in 1921 and tested the tenacity of dough and the ability of the sample to be stretched into a thin membrane by pushing air into the sample. The extensimeter had temperature control since the original model, a version with a better recorder came out in 1927. By the mid-1930s, an integrated dough mixer was added. In 1982, an air pump was introduced to pump up the bubble instead of using the gravity of a column of water to expel the air. In 1987, a timer and temperature display were added, bubble blowing was automated in the 1995 model. A completely new design, so called "NG", was introduced in 1995 and included a consistograph.
In France it has been used in regulations since at least 1963 as a criterion in milling for the composition of flours destined to the "french" type bread-baking.
KPM Analytics produces a derivative device called the which, among other uses, measures the degree of degradation due to pest and fungus, and the protection provided by insecticides and fungicides.

Description

The Chopin alveograph is composed of four parts:
  1. a "mixer" kneading-machine with an extraction passage which enables the development of the dough and the extraction of it for the preparation of the dough pieces in order to realize the alveographic test;
  2. an alveograph itself which measures the three-dimensional extension of the piece of dough, which is deformed like a bubble. That extension mode reproduces the deformation of the dough under the influence of the pushing of gas.
  3. a recording manometer or an Alveolink calculator to record the pressure;
  4. a printer.

    Testing results

The test is performed by slowly inflating the bubble and recording the pressure H vs. abscissa L. The correction coefficients are applied for compatibility with the earlier models.
Originally, the following results were collected from the pressure graph: maximum overpressure, average abscissa to rupture, swelling index, confguration ratio and deformation energy. After the introduction of computerized processing, more parameters were added, like the elasticity index, and minimum and maximum of first derivative. Pressure curve was converted into the stress–strain curve, yielding the strain hardening index and the strength coefcient.
Jødal & Larsen suggest that G, Dmax, SH and K are near-perfectly correlated to L, P, Ie and P respectively, thus the basic set of parameters obtained on the alveograph contains just six values: P, L, W, P/L, Ie and Dmin.
The measurements are typically repeated multiple times and averaged.

Maximum overpressure (P)

The maximum overpressure is the highest pressure that occurs during the test, multiplied by 1.1. P is called the dough "tenacity", often used, but has no corresponding rheological value and thus is interpreted in multiple ways.

Average abscissa to rupture (L)

The bursting of the bubble is manifested by a rapid decline in pressure. The corresponding abscissa point, L, is called "extensibility", and characterizes the maximum stratch that dough can experience without breaking. It is an important parameter in breadmaking, as high values of L make possible breads with high volume and fine crumb structure.

Swelling index (G)

The swelling index G expresses the volume of air needed to rupture the bubble. Since the air is fed at a constant rate, G is a square root of L with a scaling coefficient that, depending on the version of the manual, is either 2.22 or 2.226:. It has the same significance as L, yet also is considered to be affecting the "shortness" and "spring" of the dough.

Deformation energy (W)

The product of force and time is energy, thus the area under the pressure curve is proportional to the energy used to inflate the bubble, or deformation energy W. W factor is one of the most used values for the characterization of wheat, and is referred to as "strength". W is closely related to the percentage and quality of gluten in the dough, but is also affected by other factors, including the water absorption. Strong dough can withstand the mechanical stress of the breadmaking process through a balanced combination of viscosity and elasticity.
The value is typically expressed in Joules units. Due to numbers being low, a scaling factor is frequently used, bringing the typical values into a three-digit range.

P/L ratio

The ratio of P to L is called the confguration ratio. The high ratio reflects a strong and inextensible dough, while low values correspond to a weak and extensible one. While P/L seems to characterize a balance between tenacity and extensibility, the P/L requirements frequently do not change across the areas of use, and it is less frequently used.

Elasticity index (Ie)

The elasticity index Ie is defined as ratio of pressure corresponding to the 40 mm abscissa and the maximum overpressure P, expressed as percentage:. Since the volume of air pumped into the bubble at this point in time is about 200 ml, the 40 mm pressure is also denoted as, so
For more extensible doughs, the pressure might never reach 40 mm, and Ie cannot be determined. The 40 mm abscissa is selected to reflect the moment when the resistance to deformation is expected to no longer depend on the thickness of dough and thus reflect the internal bonding force. There is a positive correlation had been found between the Ie and the bread volume.

Dmin and Dmax

A first derivate can be taken of the pressure curve, the minimum and maximum values of the derivative are denoted Dmin and Dmax respectively. Dmin thus defined is negative, so sometimes an absolute value is used. Lower Dmin values correlate to higher volume of bread. Dmax, while reported by the alveograph, is apparently not used in practice.

Strain hardening index (SH) and strength coefficient (K)

The relationship between stress and Hencky strain can be described by a stress-strain curve, where and are empirical coefficients best-fit using the alveograph curve. The exponential part of the equation reflects the strain hardening caused by the properties of gluten network. High SH improves the condition for inflation of dough bubbles in the bread. K defines the stress when there is no strain. It is higher for more stiff or viscous dough and, probably due this mixing of two different properties in one value, used less frequently than SH.