RU2253293C2 - Method for preparing of carbohydrate-containing jellying concentrate for confectionery products - Google Patents

Abstract

FIELD: production of jellying concentrate.

SUBSTANCE: method involves squeezing juice from preliminarily prepared sugar beet deodorized with the use of above-critical carbon dioxide; extracting pomace while mixing in extraction volume of water and liquid hydrogen fluoride; blending juice and extract; introducing liquid ammonia and above-critical CO₂-extract of Mortierella sclerotiella micromycet biomass into blend; providing further extraction of said biomass by predetermined process for producing of solid residue, which is further treated with liquid ammonia; concentrating blend; treating concentrate with liquid carbon dioxide; mixing with treated solid residue of Mortierella sclerotiella micromycet biomass and heating mixture to temperature of at least 60°C.

EFFECT: increased yield of base product possessing improved structuring capability and increased thermal stability.

Description

The invention relates to a technology for the production of a gelling concentrate containing structure-forming agents of plant and microbial origin.

A known method of producing a carbohydrate-containing gelling concentrate for confectionery, involving the preparation of sugar beet root crops, thermal deodorization with liquid carbon dioxide in a microwave field, extraction to produce juice and squeezes, hydrolysis-extraction of squeezes in the presence of a peroxidase enzyme in the field of mechanical ultrasonic vibrations, separation of the extract, blending juice and extract, introduction of liquid ammonia into the blend, concentrated by vacuum evaporation, treatment of the concentrate with liquid carbon dioxide and heating to a temperature not lower than 60 ° C (RU 2076485 C1, 03/27/1997).

The disadvantages of this method are the low yield of the target product, high energy consumption and technological additives.

The technical result of the invention is to increase the yield of the target product, improve its structure-forming properties and reduce resource consumption.

This result is achieved by the fact that in the method for producing a carbohydrate-containing gelling concentrate for confectionery products, which involves preparing sugar beet root crops, thermal deodorization with carbon dioxide, squeezing to obtain juice and squeezes, hydrolysis-extracting squeezes, separating the extract, blending the juice and extract, introducing into the blend liquid ammonia, concentration by vacuum evaporation, treatment of the concentrate with liquid carbon dioxide and heating to a temperature not lower than 60 ° C, according to the invention, at heat deodorization uses carbon dioxide in the supercritical state, hydrolysis-extraction is carried out with a hydrofluoric acid solution obtained directly in the extraction volume by separately supplying water and liquid hydrogen fluoride to it, simultaneously with ammonia, the extract obtained after the biomass of the micromycete Mortierella sclerotiella is extracted with carbon dioxide in carbon dioxide state, in an amount of about 2% by weight of solids, while after extraction with carbon dioxide in a supercritical state b iomass of micromycete Mortierella sclerotiella is sequentially extracted with water, alkali, water, acid, water, alkali and water, the obtained solid residue is treated with liquid ammonia and introduced into the concentrate treated with liquid carbon dioxide in an amount equivalent to the biomass consumption of the extract introduced into the blend simultaneously with liquid ammonia, and the mixture is subjected to heating to a temperature not lower than 60 ° C.

The method is implemented as follows.

Root crops of sugar beets are prepared according to generally accepted technology by washing and inspection, and then they are cut and deodorized with carbon dioxide in a supercritical state.

It should be noted that, with the end result being the same compared to the closest analogue and the consumption of carbon dioxide, its conversion to the supercritical state by heating and compression is a less energy-intensive process compared to liquefaction combined with irradiation of raw materials with a microwave field due to the low efficiency of microwave emitters and incomplete absorption of microwave energy by sugar beets. In addition, the absence of the need to irradiate raw materials simultaneously with their processing under high pressure simplifies the hardware design of this stage of the process.

Deodorized beets are squeezed to separate juice and squeezes, Juice contains mainly soluble carbohydrates, and pectin is only in a soluble form, while pectin is mainly in bound state in squeezes. Therefore, for its most complete extraction, it is necessary to carry out the process of hydrolysis - extraction of pomace.

Hydrolysis-extraction is carried out with a solution of hydrofluoric acid obtained directly in the extraction volume. For this, water and liquid hydrogen fluoride are supplied to the extraction volume separately. In the extraction volume, liquid hydrogen fluoride boils to form a gas phase and dissolves in water with the release of heat, leading to the formation and subsequent condensation of vapors in the liquid phase. All of these processes are accompanied by the creation in the liquid medium of pressure oscillations of acoustic frequencies, intensifying chemical reactions and mass transfer processes, that is, accelerating the accumulation of dissolved carbohydrates and pectin substances in the liquid phase.

It should be noted that the rejection of the use of peroxidase at this stage of the technological process leads to a certain decrease in the average molecular weight of soluble pectin substances by eliminating the possibility of crosslinking them in solution, but at the same time excludes the possibility of combining the already extracted pectin substances with unextracted ones. This accelerates the process of hydrolysis-extraction and reduces the loss of pectin due to its deep hydrolysis, which increases the specific yield of the target product.

The dry biomass of micromycete Mortierella sclerotiella is sequentially extracted with supercritical carbon dioxide, water, alkali, water, acid, water, alkali and water, separating for later use the extract obtained in the first stage of extraction and the solid residue obtained after completion of all the above stages of extraction .

The first extract contains mainly higher polyunsaturated fatty acids, and the solid residue is mainly basic proteins. To increase the reactivity of the main proteins, the solid residue is treated with liquid ammonia. The latter, reacting with the residual amount of water, forms ammonium hydroxide, which cleaves the bound acid residues, and increases the amount of free hydroxyl groups in the main proteins.

The resulting extract and sugar beet juice are blended and liquid ammonia and the extract obtained after extraction of the biomass of micromycete Mortierella sclerotiella with supercritical carbon are introduced into the blend. In the water, which is part of the blend, liquid ammonia forms ammonium hydroxide, which neutralizes the free carboxyl groups of pectin substances, organic acids that are part of the juice and extracts, and hydrofluoric acid. As a result, the blend has an alkaline reaction. The blend thus treated is concentrated by vacuum evaporation. Alkaline environment and even distribution of unsaturated compounds in a water-soluble state due to the saponification of higher fatty acids with ammonium hydroxide by volume of the blend prevent the accumulation of hydroxymethyl furfural and other carbohydrate oxidation products in the concentrate.

The concentrate thus obtained is treated with liquid carbon dioxide. The latter, interacting with water, forms carbonic acid, which, in turn, binds ammonium ions in the concentrate, forming thermolabile salts, and increases the content of free carboxyl groups in pectin substances. The content in the concentrate of the extract from the biomass of micromycete Mortierella sclerotiella in an amount of more than 2.1-2.5% by weight of solids in this case leads to a syneresis of fatty acids. Therefore, the introduction of this extract in an amount of more than 2% by weight of solids is not recommended.

Next, a solid residue treated with liquid ammonia, obtained from the biomass of micromycete Mortierella sclerotiella, is introduced into the concentrate according to the technology described above. This leads to the interaction of free carboxyl groups of pectin substances and free hydroxyl groups of basic proteins with the formation of water and structural substances of mixed composition of high molecular weight. The mixture thus prepared is heated to a temperature not lower than 60 ° C. This leads to thermal degradation of all ammonium salts of carbonic acid and the release of ammonia and carbon dioxide from the mixture in gaseous form, that is, the liberation of the resulting target product from impurities. Heating above the mentioned temperature does not lead to the achievement of a different result, therefore, it is impractical.

An experimental verification showed that the yield of the target product by reducing the loss of pectin substances increases by 8-10% compared with the closest analogue. The strength of the jelly at the same temperature for the prototype is higher than for the control at 6-8 mm RT. Art. In addition, the prototype compared with the control has a much higher heat resistance, sufficient for its use in baking, which is impossible for the product obtained by the closest analogue.

Thus, the proposed method allows to reduce the consumption of resources to increase the specific yield of the target product with improved structure-forming ability and high heat resistance.

Claims (1)

A method for producing a carbohydrate-containing gelling concentrate for confectionery, involving the preparation of sugar beet root crops, thermal deodorization with carbon dioxide, squeezing to obtain juice and squeezes, hydrolysis-extraction of squeezes, separation of the extract, blending of juice and extract, introduction of liquid ammonia into the blend, concentration by vacuum evaporation treatment of the concentrate with liquid carbon dioxide and heating to a temperature of at least 60 ° C, characterized in that carbon dioxide is used for thermal deodorization ode in the supercritical state, hydrolysis-extraction is carried out with a solution of hydrofluoric acid, obtained directly in the extraction volume by separately supplying water and liquid hydrogen fluoride to it, simultaneously with ammonia, the extract obtained after the biomass of micromycete Mortierella sclerotiella is extracted with supercritical carbon dioxide the amount of about 2% by weight of solids, while after extraction with carbon dioxide in a supercritical state the biomass of micromycete Mortierella sclerotiella last They are thoroughly extracted with water, alkali, water, acid, water, alkali and water, the resulting solid residue is treated with liquid ammonia and introduced into a concentrate treated with liquid carbon dioxide in an amount equivalent to the biomass consumption of the extract introduced into the blend simultaneously with liquid ammonia, and heating the mixture to a temperature not lower than 60 ° C.