RU2515719C1 - Method for bioobjects drying in plasma flow - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: bioobject is placed into a gas-discharge tube wherein vacuum is created (no more than 1 mm Hg) and a high voltage source of electric current is connected with voltage within the range of 20-30 thousand V; the temperature inside the gas-discharge tube is equal to nearly 300 K. Liquid evaporated in the drying process is discharged.

EFFECT: object effective preservation for long storage life.

2 dwg

Description

The invention relates to methods for drying bioobjects intended for preservation with a view to their long-term storage, and can be used in various fields of food, medical and pharmaceutical industries.

The known types of drying are based on the obligatory supply of thermal energy to a wet body, but in various ways: convective (in the flow of a heated drying agent), contact (when the body touches a heated surface), dielectric (high-frequency currents), sublimation, radiation (IR radiation) ), acoustic (using ultrasound). [one]

In the food industry, convective and contact drying is used predominantly. The remaining species are used very rarely and are usually called special types of drying.

Convective drying is carried out in a stream of a heated drying agent, which simultaneously performs the functions of a heat carrier and a moisture carrier - a transport medium into which the removed moisture passes, and in some cases contributes to the creation of the necessary hydrodynamic environment. [Ibid.]

When organizing convective drying, certain requirements are imposed on the sterility of the drying agent and the provision of sanitary and hygienic conditions for the process. All this is its flaws.

During freeze-drying, the main part of the moisture (up to 85%) is removed in a frozen state under high vacuum (residual pressure 5-330 Pa). The heat required for freeze-drying is supplied to the material from heated surfaces or radiation from heated screens. An insignificant heat consumption (2.1-2.3 kJ / kg) allows preserving the biological properties of dried food products and medical preparations (antibiotics, blood plasma, etc.). [Ibid.]

Acoustic drying is characterized by the presence of emitters of ultrasonic vibrations, the energy source of which is the kinetic energy of the gas stream. Thanks to these emitters, the material to be dried is exposed to a sound field with an intensity level of 145 dB from the side of the gas stream. Ultrasonic drying allows the removal of moisture from the material without a significant increase in temperature, which is especially important when processing easily oxidized and heat-sensitive products. However, due to the high cost of acoustic energy, due, in particular, to the low efficiency of emitters (20–25%), ultrasonic drying is used only to a limited extent, mainly in the production of finely divided pharmaceuticals and biologically active substances (for example, antibiotics, hormonal preparations). [Ibid.]

For drying thick-walled materials, when their fast heating in the entire volume is required, in some cases drying in the field of high or ultra-high frequency currents is effective. Such drying is used for plastic and rubber products, porcelain insulators and other materials with dielectric properties. High-frequency (dielectric) dryers allow quick and even drying. [Ibid.]

During high-frequency drying, heat is supplied using an electric current field of high (10-25 MHz) and ultrahigh (2000-2500 MHz) frequencies. The composition of wet materials of plant origin includes electrolyte ions, electrons, molecules of polar and nonpolar dielectrics with dipole moments. In an electromagnetic field, dipoles are located along the field axis. Getting into an alternating electromagnetic field, they make oscillatory movements, trying to follow the fields.

However, their use is limited due to expensive equipment, high energy consumption (up to 5 kWh per 1 kg of evaporated moisture) and the need to observe special safety measures. [Ibid.]

In infrared radiation (1 = 0.77-344 microns) thermo-radiation or simply radiation dryers, a high drying speed is achieved due to the supply of a large amount of heat to the wet material. Its generators are special electric lamps with mirror reflectors installed above the surface of the material to be dried (usually transported by a conveyor) or ceramic and metal screens heated by hot gases. These dryers are compact and efficient for processing high-absorption radiant flux sheet materials and painted surfaces (e.g., paint coatings, fabrics, paper, etc.). [Ibid.]

The analysis of known drying methods shows that their common and main drawback is the mandatory heating of the material, the temperature of which depends on the duration of the process and the quality of the product. A new, previously unknown, method for drying bioobjects in a plasma stream without the obligatory heating of the product is proposed. Applied for the first time - the use of low-temperature plasma as a source of energy supply, stimulating the occurrence of electrokinetic processes in the dried product.

The objective of the invention is directed to the development of a new method of drying bioobjects in a stream of low-temperature plasma, which allows the process to be carried out without supplying thermal energy, more intensively, while ensuring high sanitary and hygienic conditions.

The technical result is a dried bioobject.

The problem is solved by the proposed method, in which the removal of liquid by evaporation and removal of the generated vapor when energy is supplied to the material to be dried, which stimulates the occurrence of electrokinetic processes, according to the invention, the energy of the low-temperature plasma obtained under the following conditions is used as the energy supplied to the dried bio-object: vacuum less 1 mm. Hg. Art. (Torr), the voltage is in the range of 20-30 thousand volts, while the temperature temperature of the low-temperature plasma depends on the difference in the masses of electrons and ions that make up the molecules or groups of molecules of the particles of the dried bioobject.

The purpose of drying, which is widely used in the food industry, agriculture, the chemical and forestry complex, the production of building materials, leather, light and other sectors of the country's economy, is to preserve the quality of raw materials, prepare them for processing, use, transportation and storage. This process is often the last technological operation preceding the release of the finished product. In this case, part of the liquid is preliminarily removed by cheaper mechanical methods, and finally by thermal methods.

The essence of any drying method is to remove moisture from the material. The main condition for the flow of any drying method is the external supply of energy (mechanical, thermal, electromagnetic waves, etc.). Consideration of the drying process at the molecular kinetic level allows a better understanding of some actually observed phenomena.

Wet materials always have molecules whose energies are enough to overcome bonds with other molecules and which are capable of breaking away from the surface of a liquid or solid and passing into the space surrounding them. This process for liquid is called evaporation (or vaporization), and for solids - sublimation (or sublimation). The removal of moisture from the surface of the material creates a difference in the concentration of moisture in the inner layers, which causes moisture to move from the inner layers to the surface of the material.

Evaporation or vaporization of a liquid occurs at any temperature, but the intensity of this process is associated with an increase in the internal energy of a substance transferred by an external energy source.

Drying in a low-temperature plasma is carried out due to the energy field of the ionized gas. The energy transferred to the wet material stimulates the occurrence and occurrence of electrokinetic processes in it, due to which moisture is removed from the material. The presence of vacuum significantly intensifies the drying process.

The word "plasma" (from the Greek. "Plasma" - "issued") in the middle of the XIX century. they began to call the colorless part of blood (without red and white bodies) and the liquid that fills living cells. In 1929, American physicists Irving Langmuir (1881-1857) and Levi Tonko (1897-1971) called plasma ionized gas in a gas discharge tube [2]. The English physicist William Crookes (1832-1919), who studied the electric discharge in rarefied air tubes, wrote: “The phenomena in evacuated tubes open up a new world for physical science in which matter can exist in the fourth state.” [3]

Plasma is usually divided into ideal and non-ideal, low-temperature and high-temperature, equilibrium and nonequilibrium, and quite often low-temperature plasma (sometimes called cold plasma) is nonequilibrium, and hot - equilibrium. In our experiments, a nonequilibrium plasma is used, the electron temperature of which is significantly lower than the temperature of the ions. This is due to the difference in the masses of the ion and electron, which complicates the process of energy exchange.

During the drying, the energy temperature of the low-temperature plasma depends on the difference in the masses of electrons and ions of which the molecules or groups of molecules of the particles of the dried bio-object are composed.

The drying temperature was 300 ° Kelvin and above. When applying temperatures below 300 ° K, the drying process is sublimation (freezing). Therefore, the substance may be in a frozen or unfrozen state.

Depending on the temperature, any substance changes its state. So, water at negative (Celsius) temperatures is in the solid state, in the range from 0 to 100 ° C - in the liquid state, above 100 ° C - in the gaseous state. If the temperature continues to rise, atoms and molecules begin to lose their electrons - they are ionized and the gas turns into a plasma. At high temperatures, the plasma is absolutely ionized - it consists only of electrons and positive ions. In physics, plasma is understood as a gas consisting of electrically charged and neutral particles, in which the total electric charge is zero. Also, plasma is a partially or fully ionized gas in which the densities of positive and negative charges are almost the same. Under laboratory conditions, plasma is formed in an electric discharge under vacuum. Distinguish between high temperature and low temperature plasma. The most widely used application is low-temperature plasma, which is used in lighting engineering, gas lasers, etc.

Experiments and studies were conducted at the TOPO laboratory (technological equipment of industry processes) at Moscow State University of Food Production (Moscow State University of Food Production) under the guidance of Professor Ilyukhin Vyacheslav Vasilievich, a new method for drying a biological object in a low-temperature plasma stream.

Since the very phenomenon of creating a low-temperature plasma has been known for a long time, therefore, studies should be carried out under certain conditions. For example, the vacuum should be less than 1 mm. Hg, voltage within 20-30 thousand volts and the use of a certain environment. Suppose water vapor gives a certain white-pink color, other substances form a luminescence of gas in a different color.

In our experimental version, rarefied air (ionization of oxygen atoms) was characterized by a dazzling white-blue light, and water vapor during the drying of the substance gave a pale pink glow in the form of Langmuir rings (waves) (photo). Other substances form a glow of gas in a different color.

To implement the method, an experimental device was created for drying biological objects in a plasma stream, shown in Fig. 1.

The device includes a gas discharge tube 1 mounted on a tripod 2 of a rubber hose 3, pump vacuum 4, and a high-voltage source of electric current 5. The Langmuir 6 rings (waves) created in gas discharge tube 1 are also shown in Fig.

The method is as follows.

A bioobject in the form of powdered milk powder in an unfrozen state or frozen in humidity of about 20-25% is placed in a gas discharge tube 1 mounted on a tripod 2, a rubber hose 3 is connected to a pump vacuum 4 and a high-voltage source of electric current 5 (GIVN) is turned on with a voltage within 20- 30 thousand volts.

In the gas discharge tube 1, a vacuum of less than 1 mm is created. Hg, which was characterized by a dazzling white-blue light. The temperature inside the discharge tube is about 300 ° K. The beginning of the drying process was shown by water vapor, which during the drying of the substance gave a soft pink glow in the form of Langmuir rings (waves), while the particles of the biological object came into motion and took the form of a spiral rotating coaxially in the direction of the luminous rings (photo, Fig.).

The end of drying was determined visually by changing the color of the glow: from a pale pink color, the Langmuir rings (waves) turn to a bright turquoise color, which corresponds to a change in the humidity of the biological object, while the time period was from 10 to 30 seconds.

After drying, turn off the high-voltage source of electric current 5, disconnect the rubber hose 3, the vacuum pump 4 and remove the dry product from the gas discharge tube 1.

A detailed state of the dried bioobject was not carried out for chemical and biological parameters, but the humidity decreased and amounted to 1.5%.

The conclusion is clear - previously unknown to specialists both in Russia and abroad, the method of the drying process takes place and further studies are needed.

This invention is at the stage of laboratory research.

Literature

1. Internet, site CHEMPORT.RU, drying.

2. Langmuir Irving "Gas filled tungsten Filament lamps high vacuum electron devices" USA, New York, 1913 p. 57.

3. Crookes William "Notes of an Inquiry into the Phenomena called Spiritual during the Years 1870-1873," Quarterly Journal of Science, 1874, p. 3.

Claims (1)

A method of drying a biological object in a plasma stream, characterized in that the biological object is placed in a gas discharge tube in which a vacuum of less than 1 mm is created. Hg and connect a high-voltage source of electric current with a voltage in the range of 20-30 thousand volts, while the temperature inside the gas discharge tube is about 300 K, the liquid evaporated during the drying process is removed.

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