
Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 297  2024 

 
 Received:  28.1.2024 

 Revised: 17.2.2024 

 Accepted: 29.2.2024 

 Published: 5.3.2024 

 
Potravinarstvo Slovak Journal of Food Sciences 

vol. 18, 2024, p. 297-312 

https://doi.org/10.5219/1959 

ISSN: 1337-0960 online 

www.potravinarstvo.com 

© 2024 Authors, CC BY-NC-ND 4.0 

 
Modelling the centrifugal mixing process of minced meat to 

optimise the production of chopped meat semi-finished products 

 
Igor Palamarchuk, Mikhailo Mushtruk, Volodymyr Vasyliv, Eugeniy Stefan, 

 Olesia Priss, Iryna Babych, Inna Karpovych, Nataliia Pushanko 
  

ABSTRACT 
One of the most important problems in ensuring the quality of mincemeat preparation in the production of 

sausages is the effective structuring of components and mixing of their ingredients. To solve this problem, 

researchers added a multifunctional admixture based on whey protein in the process of centrifugal mixing of 

the components, which determined the composition of the factor space of the investigated process. Based on 

the results of the research, the effective content of whey protein, sodium alginate, and soy fiber in the developed 

recipe was proven, which showed high characteristics in terms of fat-retaining and moisture-retaining ability, 

digestibility, pH level – activity, and other parameters. The developed formulation made it possible to improve 

the general indicator of the balance of amino acids in the product and increase the functional-technological and 

quality parameters of the developed products. The physical and mechanical characteristics of the obtained meat 

product were evaluated based on the results of physical and mathematical modelling. Modelling was carried 

out using Federman-on-Buckingham's second similarity theory and the "dimension theory" method, which 

allows the processing of the obtained experimental data in the form of a criterion equation, which was compiled 

using Froude, Euler, and Sherwood criteria. The purpose of this study was to obtain dependencies between such 

process factors as product density, the coefficient of dynamic viscosity of the technological medium, the 

ultimate shear stress, the change in the concentration of the main impurities of lactic acid in the raw material, 

the value of the diffusion coefficient and the coefficient of mass transfer in the loading mass, the weight of one 

load of products, the angular frequency of rotation of the screws of the minced meat mixer, the radius of the 

rotating working bodies, the characteristic size of the products after grinding. Using the complex criterion 

equation and the developed program, we find a recommended set of operating mode parameters for preparing 

minced meat under the conditions of centrifugal influence on the mixing process and the action of the specified 

factors. 

 
Keywords: dimension theory, similarity numbers, whey proteins, centrifugal driving forces, lactic acid 

admixture, chopped meat products, complex food additives

INTRODUCTION 
To improve the nutrition structure, the tendency to create an assortment of products enriched with vitamins, 

minerals, dietary fibers, and other biologically active substances is becoming increasingly widespread. At the 

same time, preservation of the necessary taste qualities is achieved due to functional indicators, physical and 

chemical composition, and structural combination of the main components. The development of the meat industry 

involves the production of combined meat products due to the mutual enrichment of their structures, a combination 

of functional and technological properties, an increase in biological value, and an improvement in organoleptic 


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Volume 18 298  2024 

properties, technical indicators of the finished product, a decrease in its value [1]. The generally accepted daily 

physiological norm of protein for an adult is 80 g on average, including about 50 g of animal protein [2]. The 

shortage of animal proteins contributes to the intensive development of food technologies with the optimal 

combination of meat and other raw materials to obtain biologically complete food products, which led to the 

development of the scientific direction of the development and production of meat products of combined 

composition. Serum proteins albumin and globulin have valuable biological properties, which allow us to assert 

the optimal set of vital amino acids from the point of view of nutrition physiology [3]. Such structures approach 

the amino acid scale of an "ideal" protein, a protein in which the ratio of amino acids meets the body's needs. 

Therefore, developing new food products using animal protein, particularly whey protein, allows providing meat 

products with complete animal protein, which is an urgent task. 

The expansion and improvement of the range of chopped meat semi-finished products is traced in the works 

of Mushtruk et al. [4]; the development of meat-containing products by introducing multi-component additives 

into their composition for public catering establishments takes place in the works of Bal-Prylypko et al. [5]. The 

effective combination of proteins of animal and plant origin was proven by the works of Klymenko and Vinnikov, 

in particular, when replacing meat raw materials with complex additives to improve indicators of nutritional and 

biological value with enhanced organoleptic characteristics and a decrease in their cost [6], [7]. Pasichny et al., 

Riabovol and Bal-Prylypko proved that the ratio of vegetable protein, animal, and food additives in the ratio of 

45-50: 40-45: 5-15 in the composition of cooked sausage products provides the product with high functional and 

organoleptic properties [8], [9]. Filin et al. and Kutlu et al. based on the study of the partial replacement of meat 

raw materials with wheat germ and fucus algae proved the enrichment of the food product with biologically active 

iodine, alginic acids, vitamins, and dietary fibers [10], [11]. The positive effect of c on the formation of 

organoleptic and functional properties of sausage products was confirmed by the works of Sonko et al. [12]; in 

particular, the practical addition of boiled groats is salted in the works of Israelian et al. [13], mashed beans – in 

the works of Shrana et al. [14].  

Research by Pylypchuk et al. revealed a nitrite-reducing bacterial preparation based on denitrifying 

microorganisms Staphylococcus carnosus, S.cfrnosusssp. utilize and cooled catholyte with a final pH of 8.86 and 

a redox potential (ORP) as part of the brine – 215-300 mV contributes to the formation of high organoleptic 

properties in sausage products and increases the nutritional value [15].  

The analysis of the presented and other literary sources revealed the need for systematized data and methods 

of effectively modelling the quality of chopped semi-finished products with a combined composition of raw 

materials and insufficient justification of recommendations regarding the use of complex multi-component 

additives of a given composition.  

Thus, evaluating the effectiveness of expanding the range of semi-finished meat products with a 

multifunctional additive based on raw animal and vegetable materials using physical and mathematical modelling 

is an urgent task. This study aims to obtain the dependence between the main parameters of the process of forming 

the structure of chopped meat semi-finished products with a multifunctional admixture based on milk whey 

protein by applying the necessary experimental basis, which was developed using the similarity theory. 

 
Scientific Hypothesis  
The main hypotheses of this scientific work can be considered as follows: when forming the mass of semi-

finished meat, the Sherwood criterion was chosen as the primary evaluation criterion because the provision of 

lactic acid diffusion is paramount; the use of the Froude criterion will allow to assess the increase in the driving 

force of the process due to the centrifugal forces used; the need to overcome the resistance forces of the 

technological environment justified the introduction of the Euler number. It is expected that the comprehensive 

assessment of the presented similarity numbers will allow the creation of a mathematical algorithm for describing 

the researched process, taking into account the main factors affecting it. 
 

MATERIAL AND METHODOLOGY 
Samples 

The following were used for conducting experimental research:  

• beef bone, in which the muscle tissue with a mass fraction of connective and fatty tissue does not exceed 10%, 

realtor Agrofirma "Polyssya LTD", Kyiv region, Ukraine to DSTU 6030:2008 [16]; 

• pork without cysts and semi-fat, in which muscle tissue with a mass fraction of fat tissue from 45% to 80%, 

realtor Agrofirma "Polyssya LTD", Kyiv region, Ukraine to DSTU 7158:2010 [17]; 

• multi-component stuffing, which includes lean pork and beef; 

• melange according to DSTU 8719:2017 [18]; 

• onion, realtor Agrofirma "Polyssya LTD", Kyiv region, Ukraine; 


Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 299  2024 

• specialty, realtor ATB Market. 

Chemicals 
Sodium hydroxide, NaOH (grade A, analytical grade, (Khimlaborreakt) Limited Liability Company, Ukraine). 

Methyl red, C15H15N3O2 (grade A, analytical grade, (Khimlaborreakt) Limited Liability Company, Ukraine). 

Sulfuric acid, H2SO4 (grade A, chemically pure, (Khimlaborreakt) Limited Liability Company, Ukraine). 

Petroleum ether, H3C-O-CH3 (excise, analytical grade, (Khimlaborreakt) Limited Liability Company, 

Ukraine). 

Animals, Plants and Biological Materials 
The meat of bulls obtained after the slaughter of animals up to 12 months of age and the meat of pigs up to 9 

months of age, which came from the agricultural company "Polyssya LTD" in Kyiv region, Ukraine, were used 

for the research. 

The system of proteinases, which consists of pepsin and trypsin, acts on protein substances (LLC "Alex", Kyiv, 

Ukraine) 

Instruments 
A mince mixer L5-FM2-M-340 was used to implement the mincemeat preparation process. 

Drying cabinet (SNOL, producer (Khimlaborreaktyv) Limited Liability Company, Ukraine). 

Muffle furnace (SNOL, producer (Khimlaborreaktyv) Limited Liability Company, Ukraine).  

Fat analyzer (SOX 406, producer (Khimlaborreaktyv) Limited Liability Company, China). 

Mineralizer (Velp Scientifica, producer (Khimlaborreaktyv) Limited Liability Company, Italy).  

Distiller for steam distillation (Velp Scientifica UDK 129 producer (Khimlaborreaktyv) Limited Liability 

Company, Italy).  

Automatic penetrometer (K95500, producer (Khimlaborreaktyv) Limited Liability Company, USA). 

pH meter (HI8314 HANNA, producer (Spectro lab) Limited Liability Company, Ukraine). 

Thermometer (digital laboratory thermometer TH310 Milwaukee, producer (Spectro lab) Limited Liability 

Company, Ukraine). 

Laboratory scales (AXIS BDM 3, (Spectro lab) Limited Liability Company, Ukraine). 

Laboratory Methods 
The assessment of the chemical composition of sausage products was conducted following established 

protocols: 

• Moisture content was determined using the drying method specified in DSTU ISO 1442:2005 [19].  

• Fat content was analyzed using the Soxhlet method by DSTU 8380:2015 [20]. 

• Protein proportion was determined through the Kjeldahl method [21]. 

• Ash content was measured using the Velp Scientifica DK6 device for ash mass fraction determination, 

employing the weight method as per DSTU ISO 936:2008 [22]. 

• Active acidity was studied by assessing pH levels according to DSTU ISO 2917:2001 [23]. 

• Protein mass fraction was determined utilizing the Lowry method with Folin's reagent, resulting in a blue 

coloration of the protein solution [24].  

• Plasticity of minced meat was evaluated through the pressing method based on the area of the meat stain on 

filter paper.  

• Content of the mycotoxin patulin was assessed via liquid chromatography with spectrophotometric detection 

[25].  

• Heavy metal content was determined using the atomic absorption method [26].  

• The content of radionuclides was measured using the gamma spectrometric method.  

• The temperature of the samples was recorded using a TH310 Milwaukee thermometer.  

• Sample weighing was carried out using AXIS BDM 3 scales. 

Description of the Experiment 
 Sample preparation: The preparation of samples for the above studies was carried out by the DSTU 

7963:2015 standard [27]. Sample selection was carried out by the requirements specified in DSTU 7992:2015 

[28] and DSTU 8051:2015 [29]. 

 Number of samples analyzed: 8 samples were examined: 4 samples using pork and 4 from beef. 

 Number of repeated analyses: The study was repeated 5 times, with the experimental data processed using 

mathematical statistics. 

 Number of experiment replications: Each study was carried out five times, and the number of samples 

was three, resulting in fifteen repeated analyses. 

 Design of the experiment: In the first stage, raw materials were prepared. The meat raw material, after 

curing, was ground into a sieve with a grid diameter of 2-3 mm, i.e., the characteristic size of the product after 

grinding is ℓ = 2 mm. During experimental research, mélange, a food additive, onion, spelled flour, and spices 


Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 300  2024 

were used as additional components in the production of chopped semi-finished products. The L5-FM2-M-340 

minced meat mixer is used to implement the process of preparing minced meat, in the working capacity of which 

screws with screw-type blades are mounted, which rotate towards each other. 

In the second stage, the resulting mass with admixtures of mélange, onion, breadcrumbs, and spices, with the 

addition of water, was processed in a minced meat mixer.  

The third stage was the laboratory analysis of the obtained substance. The main characteristics of the obtained 

semi-finished meat were determined, namely, moisture content, protein content, fat content, table salt content, 

moisture-binding capacity, plasticity of minced meat, digestibility of proteins, and amino acid composition of 

proteins. The critical stage was the statistical analysis of the obtained experimental data. 

 
Statistical Analysis   
The results were evaluated using statistical software Statgraphics Centurion XVII (StatPoint, USA) – 

multifactor analysis of variance (MANOVA), LSD test. Statistical processing was performed in Microsoft Excel 

2016 in combination with XLSTAT. Values were estimated using mean and standard deviations. The reliability 

of the research results was assessed according to the Student's test at a significance level of p ≤0.05 

  
RESULTS AND DISCUSSION 
The main factors of this process are the product density ρ, the coefficient of dynamic viscosity of the 

technological medium μ, the ultimate shear stress τ, the change in the concentration of the main impurities in the 

raw material ∆С, the value of the diffusion coefficient D and the mass transfer coefficient in the loading mass ꞵ, 

the weight of one loading of products Pz, angular frequency ω of rotation of the screws of the minced meat mixer, 

the radius of rotating working bodies r, the characteristic size of products after grinding ℓ. 

Modelling was carried out using Federman-Buckingham's second similarity theory and the "theory of 

dimensions" method, which allows the processing of the obtained experimental data in the form of a criterion 

equation. 

The authors of the scientific manuscripts [30], [31] investigated the centrifugal and vibrational technological 

effects on the hydrolysis of plant raw materials for producing pectin. The researchers found that with pulsed 

amplification of such a process, it is possible to increase its efficiency and design compact equipment, reduce 

electricity consumption, and improve the final product quality [32]. The authors confirmed the scientific 

hypothesis according to which vibrocentrifugal intensification of hydrolysis increases the driving force of the 

process, not only by activating the material flows of raw materials and reagents, due to the reduction of stability 

in the technological environment, therefore, a similar series of experiments should be repeated in our research 

[33], [34]. 

Taking into account the presented factors of the researched process and the peculiarities of its course, it is 

advisable to use the following criteria of similarity in the calculation: the Froude number Fr, as a measure of the 

ratio of inertial forces and weight [35]; Euler's number Eu, as a measure of the ratio of pressure forces and pressure 

velocity [36]; Sherwood's number Sh, as a measure of the ratio of the intensity of diffusion flows at the boundary 

of separation of interacting phases [37], [38]. At the first stage of the calculation, the parameters of the studied 

process presented above were decomposed according to the dimensions in Table 1. 

 
Table 1 Initial data for determining the strength characteristics of the researched process of minced meat 

preparation. 

No τ, Pа μ, Pа∙s ΔC t, s 𝚫𝐡𝒊, mm 𝚫𝝉, Pa 
𝚫𝝉

𝛕
 ƍ

𝒌𝒈

𝒎𝟑
 

1 300 850 0,04 420 0,5 80 0,26 1100 

2 400 1020 0,06 420 0,7 120 0,3 1150 

3 500 1100 0,08 420 0,9 200 0,4 1180 

 
The Froude criterion can be represented by the ratio of the acceleration of the force field induced in the process 

of mixing by centrifugal forces to the acceleration of free fall g: 

 
2

Ba r
Fr

g g


= =  (1) 

Where: 

the acceleration of the force field 𝑎𝐵 = 𝑟 ∙ 𝜔2; g is the acceleration of gravity. 

 
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Volume 18 301  2024 

The formula can determine Euler's criterion: 

2 2 2

P
Eu

S r



   
= =

   
 (2) 

 
Where: 

P is the resistance of the medium, H; S – an area of force contact action, m2; 𝜏 =
𝑃

𝑆
− ultimate shear stress, Pa; υ 

is the speed of movement of the executive bodies of the stuffing mixer: 𝑣 = 𝑟 ∙ 𝜔. 

 
The Sherwood criterion Sh is classically calculated as: 

Sh = ꞵ∙ℓ / D = ꞵ∙А / D (3) 

 
Where: 

ℓ – the characteristic size of the product after grinding, which we accept ℓ = 2 mm under the conditions of the 

studied mass transfer; D – the diffusion coefficient, which for minced masses can be taken D = 0.5∙10-9 m2/s. 

 
The following ratio can determine the mass transfer coefficient for the process under study: 

𝛽 =
𝑚

(𝑡 ∙ ∆𝐶 ∙ 𝑆)
=

𝜏

(𝑡 ∙ ∆𝐶 ∙ 𝑔)
 (4) 

 
Where: 

t is the processing time and one product load. 

 
In further studies, we use experimental data for control samples, in particular, ultimate shear stress; minced 

meat density ƍ˳ = 1100-1180 kg/m³; coefficient of dynamic viscosity; the depth of penetration of the cone into the 

mass of products according to studies of the penetration process [39], [40]. 

When the concentration of the main impurities in the raw material ∆С changes, the ultimate shear stress 

increases significantly, which leads to a significant increase in the density of minced meat ρ. For the specified 

power characteristics, we assume that Δτ/τ = Δƍ/ƍ = Δμ/μ, where Δτ, Δƍ, Δμ are the growth of the parameters of 

the mincemeat preparation process, respectively, when the ingredients under study are added to the mincemeat, 

i.e., for changes in its concentration in the form of ΔC, which is illustrated in Table 1. 

Then by the method of linear extrapolation: 

 
𝜌𝑖 = 𝜌0 (1 +
∆𝜌

𝜌𝑖
) (5) 

 
Where: 

g values Δh𝑖 is the reduction of the immersion depth of the cone according to studies of the penetration process 

in three product samples. 

 
Given a fairly large number of factors determining the process, let's replace the relationship between them with 

dependencies between the presented criteria of similarity. For this, we use the matrix of dimensions, which we 

compile with the help of Table 2.  

 
Table 2 Matrix of dimensions of the studied process of mixing the ingredients of minced sausages. 

Options ρ D ℓ ω τ g r ꞵ 

М, Kg 1    1   1 

L, m -3 2 1  -1 1 1  

T, s  -1  -1 -2 -2  -1 

Power coefficients n m c h t f j  

 
In general, the relationship between the presented parameters can be written in the form of a function: ꞵ = f 

(ρ, D, r, ω, τ, ℓ, g). 

 
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Volume 18 302  2024 

Based on the matrix of dimensions compiled in Table 2, we rewrite the presented function in the form of a 

power series: 

 
ꞵ =  K∙ ρ
n∙ D m∙ rj∙ ωh∙ τt ∙ gf∙ ℓc (6) 

 
Where: 

K is a constant coefficient. 

 
For the presented factor space, the number of variables is 6 and the number of dimensionless components is  

6 – 3 = 3 according to the π – theorem, that is, it corresponds to the number of selected similarity criteria, in 

particular, Sherwood, Euler, and Froude numbers. The matrix of dimensions compiled in Table 3 is reproduced 

in the system of equations for the power coefficients of the mass transfer equations (6): 

 
𝑛 + 𝑡 = 1
−3𝑛 + 2𝑚 + 𝑐 + 𝑡 + 𝑓 + 𝑗 = 0

−𝑚 + ℎ − 2𝑡 − 2𝑓 = −1
 (7) 

 
From equations (7) and (8) we obtain the following dependencies: 

−2𝑛 + 2𝑚 + 𝑐 + 𝑓 + 𝑗 = 1 (8) 

 
From equation (7):    

𝑡 = 1 − 𝑛 (9) 

From equation (9):    

ℎ = 1 − 𝑚 − 2𝑡 − 2𝑓 (10) 

From equation (8):    

𝑗 = 1 − 2𝑛 − 2𝑚 − 𝑐 − 𝑓 (11) 

From equation (7):    

2𝑛 = 2 − 2𝑡 (12) 

 
Using the obtained equations (7) – (12), we transform the mass transfer equation (6) of the studied minced 

meat preparation process sequentially in the following forms. 

 
ꞵ∙ℓ/D = Sh = (ω2∙r/g)-2m ∙ ℓ(c+1) ∙ ω(1+3m-2t-2f) ∙ r(1+2n-c-f) ∙ g(3n-c+t-j) ∙ ρ(1-t) ∙ D(m-1) ∙ τt (13) 

 
Sh = Fr-2m ∙ [τ/(ρ∙ω2∙r2)]t ∙ ω(1+3m-2f) ∙ ρ ∙ r(3-c-f) ∙ g(2n-c-j) ∙ D(m-1) ∙ ℓ(c+1) (14) 

 
Sh = Eut ∙ Fr(-2m-2f) ∙ ω(1+3m) ∙ r(3-c) ∙ g(2n-c-j-f) ∙ D(m-1) ∙ ℓ(c+1) (15) 

 
Taking into account equations (13-18), we obtain the general expression of the mass transfer equation of the 

process under study: 

 
Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 303  2024 

Sh = K ∙ Eut ∙ Fr(-2m-2f) (16) 

 
К = ω(1+3m) ∙ r(3-c) ∙ g(2n-c-j-f) ∙ D(m-1) ∙ ℓ(c+1) (17) 

 
To obtain initial data when performing a graph-analytical analysis of the researched process, the values of the 

similarity criteria presented above, parameters when using experimental data, and the results of the calculations 

were determined (Table 2). Using the data in Table 4 and the graph-analytical method of studying power functions, 

a graph of the function Sh = f (Eu) was constructed. This function is linear, the graph of which makes an angle α 

with the abscissa axis (Figure 1). 

 
Figure 1 Graph of a linear function Sh = f (Eu). 

Then the value of the first power coefficient is: 

t = tg α = 0,333
 (18) 

 
Using the previous method of calculation, we built a function graph using experimental data, found the angle 

γ (Figure 2) of its inclination to the abscissa axis, and determined the value of the second power coefficient. 

 
Figure 2 Graphic functions 𝑆ℎ/𝐸𝑢𝑡 = 𝑓(𝐹𝑟). 

−2𝑚 = 𝑡𝑔𝛾 = 0.237 та 𝑚 = −0.1365 (19) 

 
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Figure 3 Graphic functions Graphic functions 𝑆ℎ/(𝐸𝑢𝑡 ∙ 𝐹𝑟−2𝑚) = 𝑓(𝐹𝑟). 

Next, we built a graph of the function 𝑆ℎ/(𝐸𝑢𝑡 ∙ 𝐹𝑟−2𝑚) = 𝑓(𝐹𝑟)  (рис. 3), from which the angle of the φ 

was determined: 

 
-2f = tgφ = 0.449 (20) 

 
Then f = - 0.2245 

From the equation (7): 

n = 1- t = 0.667 

From the equation (9): 

h = 1 – m -2t – 2f = 1+ 0.1365 – 0.667 + 0.449 = 0.9195 

From the equation (8): 

– c - j = -3n + 2m – t + f = - 3∙0.667 – 0.273 – 0.333 – 0.2245 = - 2.8315 

Next, let's find the necessary dependencies: 

1 + 3m = 1 - 3∙0.1365 = 0.591 

m -1 = - 1.1365 

2n – c –j – f = 2∙0.667 – 2.883 + 0.2245 = - 1.273 

g (2n-c-j-f) = g -1.273 = 1/ 9.811.273 = 0.055 

-2m -2f = 0.273 + 0.449 = 0.772 

 
Taking into account the dependencies (16) and (17), the criterion equation of the studied process of cooking 

minced meat can be represented as: 

 
Sh = 0.055 ∙ Eu0,333 ∙ Fr0,722∙D-1,1365∙ ω0,591∙ r(3-c) ∙ ℓ(c+1) (21) 

 
Dependencies r(3-c) ∙ ℓ(c+1) can be neglected due to their insignificant impact on the minced meat preparation 

process under study. Thus, the definitively sought criterion equation of the process of cooking minced meat with 

given components is: 

 
Sh = 0.055 ∙ Eu0.333 ∙ Fr0.722∙D-1.1365∙ ω0.591 (22) 

 
To improve the quality and functional-technological characteristics of semi-finished meat, in the developed 

recipe, a combination of such elements as milk whey protein, sodium alginate, and soy fiber was provided, 

encouraging the synergistic effect of the resulting composition (Table 1).  

 
Table 1 The main components of the food additive to the meat products under investigation. 


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Volume 18 305  2024 

Product 
Content, % 

Protein Moisture Fat Ash 

Soy fiber 25.0 8.0 0.8 6.5 

Whey protein  69.5 8.0 6.0 7.2 

Sodium Alginate - 9.0 - 18.0 

 
Based on research, increasing the amount of whey protein and soy fiber in experimental samples, the viscosity 

of the mixture decreases under the conditions of increasing the speed of rotation of the working capacity. The best 

characteristics were shown by product samples containing 7.5 g of sodium alginate, 2 g of whey protein, and 3 g 

of soy fiber per 100 g of product. 

 According to such evaluation criteria, the fat-retaining and moisture-retaining ability was observed in the test 

sample, which contained a food additive of 60% sodium alginate, 16% whey protein, and 24% soy fiber. At the 

same time, the indicators of fat-holding capacity were 1.5 ml of fat/g of product and moisture-holding capacity – 

1.32 g of water/g of product. 

 With a change in the content of food additives from 8 to 16% in the mass of chopped semi-finished meat, the 

best digestibility indicators were observed, respectively within (72-74) %, which can be explained by the fact that 

in the presence of pepsin and trypsin, whey proteins quickly and are almost completely digested, while raw meat 

is digested by trypsin more slowly and incompletely. 

The influence of the content of the food additive on changes in the values of fat and water-holding capacity is 

presented in Table 2. All experimental samples showed sufficiently high indicators of these evaluation criteria, 

samples 4 and 5 were the best.  

 
Table 2 Indicators of functional and technological properties of a complex food additive. 

No 

Ingredients of food additives, g  

(per 100 g of product) 
Fat-retaining 

capacity, ml/g  

(1 ml of fat per  

1 g of product) 

Water-holding 

capacity, g/g  

(1 g of water per  

1 g of product) 
Sodium 

alginate, g 
Whey protein, g Soy fiber, g 

1 7.5 1 4 1.25 ±0.021 1.11 ±0.016 

2 7.5 1.5 3 1.15 ±0.041 1.12 ±0.016 

3 7.5 2 2 1.25 ±0.041 1.23 ±0.024 

4 7.5 2 3 1.5 ±0.163 1.32 ±0.016 

5 7.5 2 4 1.7 ±0.163 1.44 ±0.033 

 
According to the comparative analysis of the values of the active acidity of the mixture as a whole and its 

components (Table 3), it can be noted that in general the complex admixture is characterized by less than that of 

the components, except for sodium alginate; and a sufficiently low pH indicator, which justifies the feasibility of 

using the developed admixture in meat products. 

 
Table 3 Indicators of active acidity for the structural components of the investigated food additive based on 

animal and vegetable raw materials. 

No Title Active acidity (pH) 

1 Whey protein 6.501 ±0.002 

2 Sodium Alginate 6.375 ±0.079 

3 Soy fiber 6.93 ±0.065 

4 
Food additives based on animal and vegetable raw 

materials 
6.462 ±0.066 

 
For conducting experimental studies, the following rate of products (net) was used per 1 kg of meat pulp, g: 

wheat bread – 250 (25%), milk – 300 (30%), salt – 20 (2%), ground pepper – 1 (0.1%). Cutlets and balls were 

made from the prepared mass. The cutlet mass was portioned (1-2 pieces per portion), rolled in breadcrumbs, and 

given an oval-flattened shape up to 2.0 cm thick, 10-12 cm long, and 5 cm wide and fried (Figure 4). 

 
Potravinarstvo Slovak Journal of Food Sciences 

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a) 

 
b) 

 
Figure 5 Samples of chopped semi-finished products: a – experimental sample, b – control sample. 

 
The organoleptic valuation of taste and physicochemical properties of tested products showed that all tested 

parameters of quality of the experimental product surpassed the ones of the control one (Figure 5). 

 
Figure 5 Results of organoleptic valuation of control quality and experimental mincemeat samples. 

Several scientific papers discuss modelling processes related to sausage product production. These papers 

introduce various models, employing up to 10 main parameters in some cases [41]. However, some models neglect 

reference indicators or incorporate only one reference indicator [42]. This omission makes it challenging to verify 


Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 307  2024 

the reliability of the results obtained. In contrast, the authors of the paper [43] conducted a modelling process 

using only 2 parameters, potentially leading to imprecise results. 

Similar studies are outlined in the scientific works of diverse research groups, focusing on the design of 

technological equipment [44], [45], sausage product production [46], [47], and the development of technological 

schemes for various food industry products [48]. However, these studies often need to pay more attention to time 

parameters, which can significantly impact the quality indicators of the final products. 

In scientific works [49], [50], research was conducted on mixing minced meat, such as traditional mixing, 

vacuum mixing, and mechanical mixing. The authors claim that compared to the traditional method, which uses 

mechanical mixing, the centrifugal method is characterized by greater mixing efficiency with less processing 

time.  

The authors of the scientific works [51], [52] claim that the process of vacuum mixing in combination with 

the centrifugal method can be faster and more efficient because it uses the force of rotation to mix the components 

homogeneously and allows to reduce the effect of oxidation and preserve more natural taste and improve 

indicators quality of the finished product. However, organoleptic studies of the finished product were not 

conducted in the above-mentioned robots. 

From an economic point of view, considering the costs of energy, time, and materials, the authors [53], [54] 

confirmed the benefits of using the centrifugal method. Reducing processing time leads to lower energy costs, 

and efficient mixing can reduce raw material waste, contributing to savings.  

The authors [55] studied the possibility of adapting the centrifugal method for different types of meat, such as 

chicken, pork, or beef. This can significantly impact the universality of the method and its applicability in various 

branches of the meat processing industry.  

Therefore, the proposed method can be a promising solution for optimising the production process of semi-

finished meat products, ensuring improved quality and economic efficiency. 

The results obtained from the research can help improve production efficiency and final product quality. Below 

are the possible directions of research in this area: 

Simulation of the process of centrifugal mixing: 

• Development of mathematical models that describe the physical processes of centrifugal mixing of 

minced meat. 

• It considers various parameters, such as the speed of the centrifugal device, the size and shape of the 

centrifugal drum, the composition of the minced meat, and other factors that affect the mixing quality. 

Process optimisation: 

• Development of optimisation algorithms that allow finding optimal parameters of the centrifugal 

mixing process. 

• Consideration of budget, production volume, and product quality constraints. 

Study of the effect of minced meat properties: 

• Analysis of the influence of different types of meat, texture, moisture, and other characteristics of 

minced meat on the mixing process and the quality of the final product. 

• Development of recommendations on the optimal selection of the composition of minced meat for a 

certain type of chopped semi-finished products. 

Improvement of equipment: 

• Development of new technologies and improvement of centrifugal devices to increase mixing 

efficiency. 

• We are studying the possibility of using automated control systems to control process parameters. 

Quality control: 

• Development of product quality control methods at each stage of the process, including control of the 

homogeneity and structure of minced meat. 

• I use modern analysis methods like data mining and machine learning to identify anomalies and 

improve product quality. 

Study of the influence of environmental factors: 

• Study the influence of temperature, humidity, pressure, and other environmental factors on the mixing 

process and product quality. 

• Development of methods to compensate for the influence of variable conditions on the process. These 

studies can be helpful for meat cut manufacturers, helping to increase production efficiency, reduce 

costs, and improve product quality. 

 
CONCLUSION 


Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 308  2024 

The presented similarity numbers show both the depth of penetration of the oscillatory effect of the force field 

inside the product and the impact of the change in the concentration of the projected components in minced meat 

∆C on the value of the diffusion coefficient D and the mass transfer coefficient in the loading mass. It should be 

noted that the ω parameter, which characterizes the action of centrifugal forces during minced meat preparation, 

significantly impacts the studied process. Using the Composite criterion equation and the developed program, we 

find the recommended range of operating parameters for the process of cooking minced meat under conditions of 

centrifugal influence on the mixing process and the action of these factors in the implementation of the developed 

technology using an additive based on whey protein. When making mincemeat from chopped semi-finished 

products based on cutlet beef and lean pork, it turned out to be effective to use the researched complex food 

additive based on animal and vegetable raw materials in the amount of 0.5 to 1.5% in dry form; an increase in the 

mass fraction of whey protein in the range of (1.32-1.44)% was observed; which improves the general indicator 

of the balance of amino acids in the product, increases the functional-technological and quality parameters of the 

developed products. Taking into account the above-mentioned aspects will allow you to get a more complete 

picture of the effectiveness and advantages of the centrifugal method compared with other techniques for 

producing semi-finished meat products. 

 
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Funds:  
 This research received no external funding.   

Acknowledgments: 
We would like to thank you to Dr. for I. Palamdrchuk  

Conflict of Interest: 
 No potential conflict of interest was reported by the author(s).  

Ethical Statement: 
 This article does not contain any studies that would require an ethical statement. 

Contact Address:  
 

Igor Palamarchuk, National University of Life and Environmental Sciences of Ukraine, Faculty of Food 

Technology and Quality Control of Agricultural Products, Department of Processes and Equipment for Processing 

of Agricultural Production, Heroes of Defense Str., 12 B, 03040, Kyiv, Ukraine, 

E-mail: vibroprocessing@gmail.com  

 ORCID: https://orcid.org/0000-0002-0441-6586  

 
*Mikhailo Mushtruk, National University of Life and Environmental Sciences of Ukraine, Faculty of Food 

Technology and Quality Control of Agricultural Products, Department of Processes and Equipment for Processing 

of Agricultural Production, Heroes of Defense Str., 12 B, 03040, Kyiv, Ukraine, 

E-mail: mixej.1984@ukr.net  

 ORCID: https://orcid.org/0000-0002-3646-1226 

 
 Volodymyr Vasyliv, National University of Life and Environmental Sciences of Ukraine, Faculty of Food 

Technology and Quality Control of Agricultural Products, Department of Processes and Equipment for Processing 

of Agricultural Production, Heroes of Defense Str., 12 B, 03040, Kyiv, Ukraine, 

E-mail: vasiliv-vp@ukr.net 

 ORCID: https://orcid.org/ 0000-0002-2109-0522    

Eugeniy Stefan, National Technical University of Ukraine, Department of Reprography, Peremohy Ave., 37, 

03056, Kyiv, Ukraine, 
E-mail: eshtefan@ukr.net 

https://doi.org/10.3390/app12201059
https://doi.org/10.35784/iapgos.3487
https://doi.org/10.1007/978-3-030-91327-4_64
https://doi.org/10.1007/978-3-030-91327-4_64
https://doi.org/10.1111/ijfs.14530
https://doi.org/10.15587/1729-4061.2023.279286
https://doi.org/10.1016/j.gsf.2022.101493
https://doi.org/10.1093/mutage/geac023
mailto:vibroprocessing@gmail.com
https://orcid.org/0000-0002-0441-6586
mailto:mixej.1984@ukr.net
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Potravinarstvo Slovak Journal of Food Sciences 

Volume 18 312  2024 

 ORCID: https://orcid.org/0000-0002-0697-7651    
  

Olesia Priss, Tavria State Agrotechnological University, Faculty of agricultural technology and ecology, 

Department of Food Technology and Hotel and Restaurant Business, B. Khmelnitsky ave., 18, 72312, Melitopol, 

Ukraine, 

E-mail: olesia.priss@tsatu.edu.ua 

 ORCID: https://orcid.org/0000-0002-6395-4202    

  
Iryna Babych, National University of  Food Technologies, Faculty name, Educational and Scientific Institute 

of Food Technology, Department of Biotechnology of fermentative products and wine-making, Volodymyrska 

Str., 68, 01601,  Kyiv, Ukraine, 

E-mail: 5613694@ukr.net 

 ORCID: https://orcid.org/0000-0002-3058-3062   

 
Inna Karpovych, National University of  Food Technologies, Department of Sugar Technology and Water 

Preparation, Volodymyrska Str., 68, 01601,  Kyiv, Ukraine, 

E-mail: inkarp@ukr.net 

 ORCID: https://orcid.org/0000-0002-5912-7466 

 
Nataliia Pushanko, National University of  Food Technologies, Department of Sugar Technology and Water 

Preparation, Volodymyrska Str., 68, 01601,  Kyiv, Ukraine, 

E-mail: oks-n@ukr.net 
 ORCID: https://orcid.org/0000-0001-7369-2827    

  
Corresponding author: *  

 
© 2024 Authors. Published by HACCP Consulting in www.potravinarstvo.com the official website of the 

Potravinarstvo Slovak Journal of Food Sciences, owned and operated by the HACCP Consulting s.r.o., Slovakia, 

European Union www.haccp.sk. The publisher cooperate with the SLP London, UK, www.slplondon.org the 

scientific literature publisher. This is an Open Access article distributed under the terms of the Creative Commons 

Attribution License CC BY-NC-ND 4.0 https://creativecommons.org/licenses/by-nc-nd/4.0/, which permits non-

commercial re-use, distribution, and reproduction in any medium, provided the original work is properly cited, 

and is not altered, transformed, or built upon in any way.  

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