RU2347738C1 - Method of pouring wine in disposable cans - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to wine industry and can be used in pouring wines. Wine material is subjected to bentonite fining during mixing in a vessel subjected to acoustic oscillations created by hydro acoustic radiators. Then, wine material is filtered, pasteurised, packed up in the disposable cans sterilised as shown above. Cans with wine are transferred to pouring to degas oxygen of air from filled cans by ultrasound, to add nitrogen, to cork the cans, to carry out stepwise pasteurisation with a simultaneous washing of the can external surface, to dry the cans, to pack them into container and to place in storage. Cans pasteurisation and external surface washing are performed with temperature of water increased stepwise from 25 to 30°C up to 63 to 69°C with subsequent stepwise decrease in water temperature.

EFFECT: intensified pouring, decreased reject, improved organoleptic quality of wine in its long storage.

9 cl

Description

The invention relates to the food industry and can be used for bottling wines.

There is a known method of wine production, according to which the juice is cooled, treated with bentonite in a container with a magnetostrictive sound emitter, blended, desulfitized, filtered, pasteurized, fermented, the calculated amount of sugar and alcohol is added, kept at elevated temperature, cooled and sent for bottling ( SU 190852, 1967).

As a result of the combined action of ultrasound and bentonite, clarification of the juice is achieved within 2-4 hours.

There is a method of pouring wine into aluminum cans, according to which the wine is pasted with egg white, cooled, filled with two-component aluminum cans, the inner surface of which is coated with an epoxy resin coating, nitrogen is added and sealed with an aluminum lid so that the pressure inside the can is 25-40 lb / in ² (RU 2288144, 2006).

Tests have shown that the aluminum content in wine after storage for 6 months increases by 36-44%.

The closest in technical essence and the achieved result to the proposed method is a method of bottling wine in disposable metal cans, the inner surface of which is varnished, which includes preparing wine material, filtering from mechanical impurities, pasteurization, filtering on a microbiological filter, washing cans whose inner surface is coated varnish, softened with water, their sterilization, filling with wine, supply of nitrogen gas to cans, corking with a lid, packaging of cans and storage (RU 2129982, 1999).

The disadvantage of this method is the reduction in the quality of wine during storage.

The objective of the present invention is to increase the shelf life of wine without reducing its organoleptic properties and the intensification of the processes of preparation of wine material and, accordingly, bottling of wine.

The problem is solved by the described method of pouring wine into disposable cans, which includes preparing wine material, filtering and pasteurizing wine material, washing the cans with softened water, filling the cans with wine, supplying nitrogen to the cans filled with wine, closing the lid, packing and storing, while preparing the wine material by feeding into it bentonite with stirring in a vessel equipped with low frequency sonar emitters providing oscillation intensity corresponding to To increase the sound pressure, at which a cavitation threshold occurs, the cans are washed with softened water, subjected to ultrasonic sterilization in the cavitation mode, by directly supplying water jets to the inner surface of the cans, before supplying nitrogen to the wine-filled cans, the oxygen is degassed from the bottom using ultrasonic vibrations directed from the bottom to the neck of the can, after clogging the cans, they pasteurize the wine cans and simultaneously wash the outer surface of the cans in water, etc. stepwise raising the temperature from 25-30 to 63-69 ° C and subsequently stepwise lowering the water temperature.

The method provides that after pasteurization of the wine cans, drying is carried out by blowing air to the outer surface of the cans, and then the packaging and storage of the wine cans.

Preferably, the mixing of the wine material with bentonite is carried out at room temperature for 10-17 minutes, after which the product is kept.

Preferably, the sterilization of softened water is carried out in a pipeline under a pressure of 2.5-3.0 atm, with a frequency of ultrasonic vibrations of 18 kHz and their intensity of 7-10 W / cm ² .

The direct supply of sterilized water for washing the inner surface of the cans is mainly carried out by supplying water under a pressure of 2.5-3.0 atm to the inlet of a fan-shaped sonar emitter, the output nozzle of which is placed at a distance of 3-5 mm from the neck of the can, ensuring the twisting of water jets inside cans.

The method involves bottling wine in aluminum cans, the inner surface of which is provided with an epoxy or teflon coating.

Degassing is preferably carried out at a frequency of ultrasonic vibrations equal to 44 kHz, with an intensity of 0.7-1.0 W / cm ² supplied to the bottom of the can through a layer of water whose thickness is 1/4 of the wavelength of the excited ultrasonic vibrations.

Mostly, the supply of gaseous nitrogen is carried out until the pressure in the sealed can is equal to 0.15-0.17 MPa.

In the optimal mode, pasteurization of wine cans and washing of their outer surface is done under the shower with a stepwise change in water temperature in the following sequence, ° C: 25-30, 48-50, 55-60, 63-69, 55-60, 48-50 25-30.

The essence of the claimed method is as follows.

The applicant has established that the use of hydroacoustic emitters in the process of gluing wine material while mixing it with bentonite makes it possible to obtain wine material with a high degree of transparency and purify it of nitrogen compounds, while the selected mode at this stage of the process provides a high rate of disaggregation and swelling of bentonite with a uniform distribution over the volume of the tank, which allows you to enter a small amount of bentonite in the process. The oscillation intensity at which the claimed technical result is achieved is chosen corresponding to the sound pressure at which a cavitation threshold occurs. It should be noted that a specific value of the intensity of the oscillations, which corresponds to the threshold of cavitation, is selected experimentally by known methods for each batch of wine material supplied to the bottling. The applicant has established that at sound pressure values below the cavitation threshold, the quality of wine material cleaning is insufficient, and at values above the cavitation threshold, i.e. under developed cavitation, there is an increased degree of dispersibility of bentonite, flotation of small particles and, accordingly, a deterioration in the process of gluing wine material, which subsequently leads to a deterioration in the organoleptic properties of wine during storage. The selected ultrasonic treatment mode at this stage provides an intensive and high-quality flow of the process of gluing wine material.

The ultrasonic effect on softened water in the pipeline immediately before the water supply for washing the cans ensures high sterility of the water, which leads to an increase in the shelf life of wine without compromising its organoleptic properties. With an optimal frequency of ultrasonic vibrations equal to 18 kHz, a decrease in their intensity below 7 W / cm ² does not ensure the complete destruction of microorganisms, and an intensity exceeding 10 W / cm ² can lead to erosion of the metal and an undesirable increase in water temperature.

Wash water under pressure is fed to the entrance of the resonator chambers of hydroacoustic emitters, providing fan-rotational movement of water jets inside the can with a frequency of 1-6 kHz, while the output nozzle of the emitter is placed at a minimum distance from its neck. The mentioned actions ensure high sterility of the inner surface of the can, which in turn leads to an increase in the quality of wine during storage in banks.

After pouring the wine into the cans, the dissolved oxygen is degassed using ultrasonic vibrations directed from the bottom up, at the optimum frequency and intensity. The bottoms of wine cans are immersed in a layer of water, the thickness of which in the optimal mode is 8.5 mm, which corresponds to a quarter of the wavelength used in ultrasonic processing. The selected method of transmitting ultrasonic vibrations leads to the effective degassing of oxygen from wine, creating conditions that impede the development of microorganisms that cause oxidation and damage to wine during storage.

The process of pasting wine material, the above conditions, as well as the washing of cans using the methods described above, reduced the amount of nitrogen supplied to them and, accordingly, the pressure inside the can, which reduces waste during subsequent blockage of cans and increases the yield by 7 -10%. At the same time, the pressure inside the can of 0.15-0.17 MPa turned out to be sufficient to provide the necessary rigidity of the corked cans, which in turn helps to increase the shelf life of wine without compromising its quality.

Carrying out pasteurization of cans in the claimed mode is optimal for obtaining a quality product. At the same time, the process is organized in such a way that it becomes possible to simultaneously wash the outer surface of the cans with pasteurization water, used for pasteurization.

Additionally, it should be noted that the claimed method allows for high-quality bottling of non-spill-resistant wine materials in contrast to the method adopted for the prototype.

An example implementation of the method.

Non-spill resistant wine material (dry table red Cabernet) in the amount of 10 tons is fed into a container with sonar emitters mounted in it. The feed is carried out at the input of the emitters using a pump that creates a pressure of 3 atm. At the exit from the nozzle of the radiator, acoustic oscillations of low frequency - 4 kHz are excited. The vibration intensity for this wine material, corresponding to the cavitation threshold, was preliminarily selected experimentally and turned out to be equal to 1.2 W / cm ² . At the same time, bentonite powder in an amount of 2 kg is fed into the container. Due to the occurrence of alternating pressure during the excitation of acoustic vibrations, a uniform distribution of bentonite particles in the vessel occurs, the pore of bentonite expands and the wine material diffuses into the expanded pores, while air oxygen is released from the pores of bentonite. The process of swelling of bentonite at 18 ° C takes 15 minutes. Then the pump is turned off and the resulting suspension is incubated for 27 hours. After exposure, the process of gluing wine material is completed and it is pasteurized at 65 ° C for 4 minutes, then filtered and cooled to 4 ° C. The filtered material is sent to a container, where it is aged for 10 days under conditions that exclude oxidation. In case of insufficient transparency, the wine material is additionally filtered and sent to the bottling line.

Before bottling the jars are washed as follows. Softened non-sterile water is supplied through a pipeline with an ultrasonic device mounted in it, consisting of a chamber, a ПМС-15А18 transducer and a VT-9 waveguide-emitting system made of titanium. The converter is powered by a generator of the brand UZG-2-4M. Water is supplied at a pressure of 2.5 atm. Water treatment is carried out in the pipeline in the developed cavitation mode with an oscillation intensity of 8 W / cm ² at a frequency of 18 kHz. Sterilized softened water under a pressure of 2.5 atm is fed to the inlet of the sonar emitter, the output nozzle of which is placed at a distance of 3 mm from the neck of the can and is oriented along the horizontal axis. When water passes through the emitter in a jet, oscillations with a frequency of 3 kHz are excited, the water jets twist, take the form of a fan, which ensures high-quality washing of the entire inner surface of the can. The flushing line is equipped with at least two sonar emitters.

The washed cans are conveyed by a conveyor to a tapping apparatus, which fills the cans with wine at a temperature of 10 ° C. For bottling use cans with a capacity of 330 ml, coated inside with epoxy varnish or equipped with a Teflon coating.

Cans filled with wine are conveyed through a conveyor to degass air oxygen. To this end, the cans are placed in a 8.5 mm thick water layer created on the radiating surface of the PMS-44 diaphragm type transducer. The degassing process is carried out at a frequency of ultrasonic vibrations of 44 kHz and an intensity of 0.8 W / cm ² in the direction of vibrations from the bottom up (from the bottom to the neck of the can).

After degassing, the cans of wine are fed through a conveyor to a dosed liquid nitrogen supply unit. According to the sensor signal, liquid nitrogen is supplied to each can for a period of 12 milliseconds with a temperature of minus 190 - minus 185 ° C and the cans are corked with lids to a can pressure of 0.15 MPa.

Hermetically sealed cans are fed to a pasteurization unit equipped with a shower unit containing several nozzles, each of which is supplied with water with a different temperature. Set the stepped mode of water supply to the banks of wine in accordance with the following scheme: 30-48-57-6-57-48-30 ° C. Along with pasteurization, the external surface of the wine cans is washed.

After pasteurization, the cans are dried by blowing them with cold air, packaged and sent to the finished goods warehouse.

Tests showed the following.

When storing cans for 6 months at a temperature of 30 ° C, the aluminum content in wine increased by 22% compared to the initial content, which is two times less than the increase in the content of aluminum ions in wine subjected to bottling according to the method adopted for the prototype and according to the method specified as an analogue. Reducing the content of aluminum ions in wine improves its taste. The organoleptic properties of the wine did not change during its storage for 6 months.

It should also be noted that the process in accordance with the claimed method allows to reduce the iron content in the finished product, which leads to an increase in its quality.

Similarly, the filling of the white wine “Shardane” was carried out and the preservation of the high quality of wine during 6-12 months of storage was also noted.

Thus, the proposed method allows to intensify and optimize the process of preparing wine material and pouring wine into aluminum disposable cans at low material and energy costs, and to improve the organoleptic properties of the product during long-term storage.

Claims (9)

1. The method of bottling wine in disposable cans, including preparing wine material, filtering and pasteurizing wine material, washing the cans with softened water, filling the cans with wine, supplying nitrogen to the wine-filled cans, corking the lid, packing and storing the wine cans, characterized in that the preparation of the wine material carried out by feeding bentonite into it with stirring in a tank equipped with low frequency sonar emitters, providing oscillation intensity corresponding to the sound pressure I, at which a cavitation threshold arises, washing the cans is carried out with softened water, subjected to ultrasound sterilization in the cavitation mode, by directly supplying water jets to the inner surface of the cans, before supplying nitrogen to the wine-filled cans, air oxygen is degassed from them using ultrasonic vibrations directed from the bottom to the neck of the can, after clogging, the pasteurization process of the cans of wine and the simultaneous washing of the outer surface of the cans in water with a stepwise rise in temperature atura of water from 25-30 ° C to 63-69 ° C and the subsequent stepwise decrease in water temperature. 2. The method according to claim 1, characterized in that after pasteurization of the wine cans, their outer surface is dried by blowing air, then they are packed and stored. 3. The method according to claim 1, characterized in that the mixing of the wine material with bentonite is carried out at room temperature for 10-17 minutes, after which the product is kept. 4. The method according to claim 1, characterized in that the sterilization of softened water is carried out under a pressure of 2.5-3.0 atm in the pipeline, with a frequency of ultrasonic vibrations of 18 kHz and their intensity of 7-10 W / cm ² . 5. The method according to claim 1, characterized in that the direct supply of sterilized softened water for washing the inner surface of the cans is carried out by supplying it under a pressure of 2.5-3.0 atm to the inlet of the fan-shaped sonar emitter, the output nozzle of which is placed at a distance of 3 -5 mm from the neck of the can with the provision of twisting jets of water inside the can. 6. The method according to claim 1, characterized in that the bottling of wine is carried out in aluminum cans, the inner surface of which is equipped with an epoxy or teflon coating. 7. The method according to claim 1, characterized in that the degassing is carried out at a frequency of ultrasonic vibrations equal to 44 kHz, with an oscillation intensity of 0.7-1.0 W / cm ² supplied to the bottom of the can through a layer of water whose thickness is 1 / 4 wavelengths of excited ultrasonic vibrations. 8. The method according to claim 1, characterized in that the supply of gaseous nitrogen is carried out until the pressure in the sealed bank is 0.15-0.17 MPa. 9. The method according to claim 1, characterized in that the pasteurization of the cans of wine and the washing of their outer surface is performed under the shower with a stepwise change in water temperature in the following sequence, ° C: 25-30, 48-50, 55-60, 63- 69, 55-60, 48-50, 25-30.