RU2504209C1 - Feed triticale grain flakes production method - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: invention is related to feedstuff industry. The feed triticale grain flakes production method involves impurities removal from grains, grains soaking in water at a temperature of 18-20°C during 34 hours till grains moisture content is equal to 38-40% and grains drying with infrared rays. The said drying is performed at wave length amounting to 0.9-1.1 mcm with radiant flux density equal to 12-14 kW/m² during 2.5-3.0 minutes till moisture content is equal to 30-32%. Then grains are treated with infrared rays at wave length amounting to 0.9-1.1 mcm with radiant flux density equal to 18-20 kW/m² during 100-110 sec till the grains temperature is equal to 160-170°C. Grains are flattened into 0.6-0.7 mm thick flakes.

EFFECT: high yield and high feed and biological value of the ready product.

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Description

The invention relates to the feed industry and, in particular, is intended for the production of a feed product from feed grains of triticale in the form of flakes.

A known method of manufacturing a product ready for use, comprising cleaning the feedstock from impurities and dust, calibrating the grain to the same size, treating with hot steam with a pressure of from 1.5 to 4.0 kg / cm ² and a temperature of from 100 to 300 ° C and flattening in a roll crusher with the formation of flakes, which are dried to a moisture content of 10%. Cleaning is carried out by crushing or polishing grains, air aspiration and washing with water at ambient temperature [1].

The disadvantage of this method is the low yield and low quality.

Closest to the proposed method in terms of technical nature and the achieved effect is a method of producing a ready-to-eat product, which involves cleaning grain from impurities, treating it with IR rays for 20-30 s to a moisture content of 6-8%, which does not allow drying and roasting of grains , and immediately after IR processing, flattening it into flakes with a thickness of 1.0-1.2 mm [2].

The disadvantage of this method is the low yield and low quality of the finished product, which is due to the IR treatment of triticale grains in the dry state, resulting in insufficient degradation of starch during processing with IR rays and conditioning, and also a large amount of crumbs is formed. In addition, the resulting finished product has a reduced biological value, since this processing method does not reduce the activity of trypsin inhibitors of triticale grains, which are a serious anti-nutritional factor.

The objective of the invention is to increase yield, improve quality and increase the biological value of the finished product.

This object is achieved in that in the production of a feed product, which includes cleaning impurities from triticale grains, soaking the grains, drying with infrared rays, processing with infrared rays, followed by conditioning in flakes, the difference is that the grain is dried with infrared rays at a wavelength 0.9-1.1 μm and a radiant flux density of 12-14 kW / m ² for 2.5-3.0 min to a moisture content of 30-32%, grain processing by infrared rays is carried out at a wavelength of 0.9-1 , 1 μm and the density of the radiant flux of 18-20 kW / m ² for 100-110 s until the grain reaches a temperature of 160-170 ° C after hot flattening flakes 0.6-0.7 mm thick. Grain drying is preceded by soaking in water at a temperature of 18-20 ° C for 34 hours to a final moisture content of 38-40%.

The technical result consists in obtaining the finished product, with a large yield, with high feed and biological value; the resulting product has improved quality and is better absorbed by the animal body.

Soaking grain in water is carried out by air-water method, which includes changing the water, washing the grain, aerating with air, suppressing microflora by adding bleach. Soaking in water is necessary both for subsequent destructive processes (gelatinization and dextrinization of starch) in the grain during IR processing, and for the inactivation of trypsin inhibitors. When soaking, the grain is pecked and a deep rearrangement of the entire enzyme complex occurs, accompanied by complete inactivation of proteinase inhibitors. In addition, wet grain becomes more ductile.

The choice of the soaking temperature of 18-20 ° C is due to the good absorption of water by the grain at a given temperature. At temperatures below 18 ° C, the grain absorbs water longer. At a temperature of more than 20 ° C, additional costs for heating water are required and microflora on grain is developing very strongly.

Soaking for 34 hours ensures that the grain reaches a moisture content of 38-40%, as well as the inactivation of trypsin inhibitors. When the grain is soaked for less than 34 hours, it does not reach the required moisture content of 38%, trypsin inhibitors partially retain their activity. When the grain is soaked for more than 34 hours, it is wetted to more than 40% moisture and may begin to germinate.

Drying grain after soaking is necessary to prevent caking of grain with high humidity, as well as for more even distribution of moistened grain on the conveyor belt before intensive infrared heating, which in turn prevents the appearance of charred triticale grains.

Grain drying is carried out by infrared rays. With slow IR heating of the grain, its gradual drying occurs. The moisture contained in the grain is removed from it without disturbing the grain structure. The heating rate depends on the density of the incident flux of infrared radiation; the higher the density of the incident stream, the higher the heating rate of the grain.

Drying of triticale grain occurs at a wavelength of infrared rays of 0.9-1.1 μm and an incident flux density of 12-14 kW / m ² for 2.5-3.0 minutes As a result, grain moisture is reduced to 30-32%. The grain is heated to a temperature of 45-50 ° C.

When IR radiation with a wavelength of less than 0.9 μm and a density of the radiant flux of less than 12 kW / m ² there is a very weak heating of the grain, which significantly lengthens the drying process in time. Under IR irradiation with a wavelength of more than 1.1 μm and a radiant flux density of more than 14 kW / m ² , processes of structural change in grain begin, as well as charring of individual grains.

The processing time of 2.5-3.0 minutes is due to the need to evaporate water from feed grain and heat it to a drying temperature of 45-50 ° C. When processing for less than 2.5 minutes, drying of the grain does not occur, and when processing for more than 3.0 minutes, the grain begins to overheat and over-fry.

At a grain drying temperature of more than 50 ° C, an inappropriate increase in energy consumption occurs, the process of frying individual grains begins. At temperatures below 45 ° C, drying of the grain proceeds very slowly.

The final humidity after drying of 30-32% provides the amount of water in the grain that is necessary to participate in the expansion process, as well as to destroy the triticale grain structure (dextrinization and gelatinization of starch) during further IR processing and conditioning. If the final moisture content is less than 30%, then the destructive processes in the grain proceed less intensively and the quality of the finished product is low. At a moisture content of more than 32%, the grain is caked and can germinate, in addition, the energy costs associated with IR processing and flaking are significantly increased.

The use of a short-wavelength range of infrared radiation of 0.9-1.1 μm for heat treatment of grain corresponds to the maximum energy absorption by water molecules and -OH hydroxyl group, the use of a flux density of 18-20 kW / m ² allows you to heat the grain simultaneously over the entire volume. As a result, the moisture in the grain is intensively heated, which leads to an increase in the internal pressure of the vapor-air medium in the grain and the “swelling” of the latter.

When IR radiation with a wavelength of less than 0.9 μm and a density of the radiant flux of less than 18 kW / m ² there is a significant destruction of enzymes and vitamins, which reduces the feed value of the product. When using a radiant flux with a wavelength of more than 1.1 μm and a radiant flux density of more than 20 kW / m, most of the radiant flux is absorbed by the surface layers of grain, which leads to their significant overheating and, as a consequence, to carbonization.

Heating grain to a temperature of 160-170 ° C is necessary for the evaporation of part of the bound moisture and causes the corresponding destruction of the grain structure and starch granules, the destruction of starch to 13-15% with the formation of easily digestible products - dextrins, an increase in the content of water-soluble substances in triticale grain to 18-20 % In this case, the grain moisture is reduced to 12-13%. Grain acquires a porous structure with a bulk density of 380-420 g / l at 550-600 g / l of the original.

When processing grain to a temperature of less than 160 ° C, insufficient dextrinization of starch occurs, the amount of water-soluble substances increases slightly, therefore the product is of poor quality. When processing grain with IR rays to a temperature of more than 170 ° C, it is burned.

The processing time of 100-110 s is due to the need to heat the grain to a predetermined temperature. When processing grain for less than 100 s, the necessary biochemical changes do not occur in it. When processing grain for more than 110 s, it is burned.

The grain is flattened in a hot state with a temperature of 150-160 ° C, the decrease of which after IR treatment is due to free air convection.

Grain crushing at a temperature of 150-160 ° C and a moisture content of 12-13% is due to the presence of gelatinized starch in it, which has the character of a gel. The grain is plastic, the starch granules are connected by molecular filaments, which gives the gel a certain strength, which increases when the grain is cooled after conditioning.

When the grain temperature is less than 150 ° C and humidity less than 12%, it does not have sufficient ductility and, as a result of this, a lot of crumbs are formed when flattened, resulting in a decrease in the yield of the finished product.

When crushing grain with a moisture content of more than 13%, the finished product (flakes) is unstable during storage and requires additional drying. At temperatures above 160 ° C, the process of evaporation of moisture from feed grain is intensified, which leads to an increase in its brittleness when flattening.

With a thickness of flakes of 0.6-0.7 mm, the yield of the finished product is 95-97% with high quality indicators of flakes.

When crushing grain into flakes with a thickness of less than 0.6 mm, a lot of crumbs are formed, which reduces the yield of the finished product. When crushing grain into flakes with a thickness of more than 0.7 mm, the quality of the finished product decreases due to its insufficient mechanical destruction.

The method is as follows.

Triticale grain with a moisture content of 12-14% is cleaned of impurities, soaked in water with a temperature of 18-20 ° C for 34 hours to a final moisture content of 38-40%, dried by infrared rays at a wavelength of 0.9-1.1 μm and density a radiant flux of 12-14 kW / m ² for 2.5-3.0 min to a moisture content of 30-32%, is subjected to treatment with IR rays at a wavelength of 0.9-1.1 μm and a density of radiant flux of 18-20 kW / m ² for 100-110 s. In this case, the temperature inside the grain reaches 160-170 ° C, and its humidity decreases to 12-13%. Hot grain (grain temperature 150-160 ° C) is flattened into flakes 0.6-0.7 mm thick.

Example 1. The triticale grain with a moisture content of 12% is cleaned of impurities, soaked for 34 hours at a water temperature of 18 ° C to a moisture content of 38%, dried with IR rays at a wavelength of 0.9 μm and a radiation flux density of 12 kW / m ² for 2, 5 minutes to a moisture content of 32%, they are subjected to IR treatment at a wavelength of 0.9 μm and a radiation flux density of 18 kW / m ² for 100 s. The temperature inside the grain reaches 160 ° C. Then the grain is flattened on rolls into flakes 0.6 mm thick.

The yield of flakes is 95%, the amount of dextrins is 13.0%, the content of water-soluble substances is 18.2%, the bulk mass of flakes is 190 g / l. Trypsin inhibitors are inactivated.

Example 2. The triticale grain with a moisture content of 13% is cleaned of impurities, soaked for 34 hours at a water temperature of 19 ° C to a moisture content of 39%, dried with infrared rays at a wavelength of 1.0 μm and a radiant flux density of 13 kW / m ² for 2, 8 min to a moisture content of 31%, subjected to IR treatment at a wavelength of 1.0 μm and a density of radiant flux of 19 kW / m ² for 105 s. The temperature inside the grain reaches 165 ° C. Then the grain is flattened on rolls into flakes 0.6 mm thick.

The yield of flakes is 96%, the amount of dextrins is 14.0%, the content of water-soluble substances is 19.0%, the bulk mass of flakes is 180 g / l. Trypsin inhibitors are inactivated.

Example 3. Grain of triticale with a moisture content of 14% is cleaned of impurities, soaked for 34 hours at a water temperature of 20 ° C to a moisture content of 40%, dried with IR rays at a wavelength of 1.1 μm and a radiation flux density of 14 kW / m for 3.0 min to a moisture content of 30%, is subjected to IR treatment at a wavelength of 1.1 μm and a radiation flux density of 20 kW / m ² for 110 s. The temperature inside the grain reaches 170 ° C. Then the grain is flattened on rolls into flakes 0.7 mm thick.

The yield of flakes is 97%, the amount of dextrins is 15.0%, the content of water-soluble substances is 20.0%, the bulk mass of flakes is 170 g / l. Trypsin inhibitors are inactivated.

To prove the optimality of the parameters proposed in the claims, additional studies were carried out using transcendental values.

Example 4. The triticale grain with a moisture content of 11% is cleaned of impurities, soaked for 33 hours at a water temperature of 17 ° C to a moisture content of 37%, dried with IR rays at a wavelength of 0.8 μm and a radiation flux density of 11 kW / m for 2.0 min to a moisture content of 34%, is subjected to IR treatment at a wavelength of 0.8 μm and a radiation flux density of 17 kW / m ² for 90 s. The temperature inside the grain reaches 140 ° C. Then the grain is flattened on rolls into flakes 0.5 mm thick.

The yield of flakes is 94%, the amount of dextrins is 11.0%, the content of water-soluble substances is 16.0%, the bulk mass of flakes is 210 g / l. Partial inactivation of trypsin inhibitors occurs.

Example 5. The triticale grain with a moisture content of 15% is cleaned of impurities, soaked for 35 hours at a water temperature of 21 ° C to a moisture content of 42%, dried with IR rays at a wavelength of 1.2 μm and a radiation flux density of 15 kW / m ² for 3, 5 minutes to a moisture content of 28%, subjected to IR treatment at a wavelength of 1.2 μm and a density of radiant flux of 21 kW / m ² for 120 s. The temperature inside the grain reaches 190 ° C. Then the grain is crushed on rolls into flakes with a thickness of 0.8 mm.

The yield of flakes is 85%, the amount of dextrins is 16.0%, the content of water-soluble substances is 22.0%, the bulk mass of flakes is 180 g / l. Trypsin inhibitors are inactivated.

Thus, when using the operating parameters in example 4, the yield of flakes decreases, the number of dextrins, water-soluble substances decreases, the bulk mass of flakes increases, while the implementation of the method of example 5 allows to increase the number of dextrins and water-soluble substances, reduce the bulk mass of flakes, however, when this is the burning of grain, resulting in reduced yield of flakes. In both example 4 and example 5, inactivation of trypsin inhibitors occurs.

Therefore, the use of the invention, in comparison with the prototype, allows to increase the yield of flakes to 95-97%, to increase the value of the finished product by increasing the number of dextrins from 1.5-2.0% to 13-15%, increasing the content of water-soluble substances to 18 -20%, reducing the bulk density of flakes to 26%, reducing the thickness of the flakes from 1.0-1.2 mm to 0.6-0.7 mm. As a result, the finished product is better absorbed. In addition, the invention allows to completely inactivate trypsin inhibitors, thereby the feed product becomes biologically more complete.

Information sources

1.1, 115, 513. Rye flakes, A. Heyman A.B. April, 1966 [24 May, 1965] No. 21976/65 Heading A2Q, A23L 1/10.

2. UK application No. 1311066, 1973, No. 4382, A2Q, A23L 1/10.

Claims (1)

A method of producing flakes from feed grain of triticale, including cleaning grain from impurities, soaking the grain, drying the grain with infrared rays, treating it with infrared rays, followed by conditioning in the flakes, characterized in that the soaking of the grain in water is carried out at a temperature of 18-20 ° C within 34 hours until the grain reaches a moisture content of 38-40%, the grain is dried by infrared rays at a wavelength of 0.9-1.1 μm and a radiant flux density of 12-14 kW / m ² for 2.5-3.0 min to a moisture content of 30-32%, grain processing with IR rays is carried out at a wavelength of 0.9-1.1 μm and a density of radiant flow of 18-20 kW / m ² for 100-110 s until the grain reaches a temperature of 160-170 ° C, followed by flattening into flakes 0.6-0.7 mm thick.