RU2656346C2 - Low-temperature conservation device with the disinfection and freshness preservation functions - Google Patents

Abstract

FIELD: electrical equipment.

SUBSTANCE: low-temperature preservation device with the disinfection and freshness preservation functions represents chambers, low-temperature electronic emission unit, cooling system, electrical system and housing. Electron emission unit emits electrons and forms the certain density nanoparticles with the negative electric charge, providing the conservation chambers disinfection. Nanoparticles with a negative electrical charge sticking to the stored products surface and water molecules, form hydration films on canned products while maintaining the water content therein.

EFFECT: use of this invention ensures the canned articles freshness and increases the canned products shelf life.

3 cl, 3 dwg

Description

FIELD OF TECHNOLOGY

The present invention is a device for low-temperature conservation, and more specifically, a low-temperature storage device with the functions of disinfection and preservation of freshness of stored products. Due to the use of nanoparticles with a negative electric discharge, the low-temperature conservation device finds its application in various fields, including domestic use, for sanitary processing, in the food industry, scientific technologies, industrial enterprises, agriculture, etc.

BACKGROUND

Various low-temperature preservation devices are used all over the world, including household heaters, warehouse cooling and heating systems, various low-temperature preservation devices for the storage, transportation and sale of refrigerated products, as well as in medicine, industry and the agricultural industry and for scientific research. These devices provide the following: the destruction of bacteria under the influence of low temperature, while controlling and suppressing the growth and reproduction of bacteria in the stored product using low-temperature preservation. However, essentially a large number of bacteria is stored in the product subjected to low-temperature preservation, and some cryogenic microorganisms can multiply and spread even at temperatures below -20 ° C. For example, various meat products stored in a frozen state can deteriorate as a result of the spread of psychrophilic bacteria and mold, which shortens their shelf life. In addition, at present, when operating all devices of low-temperature preservation, they also face two problems: they are associated with a deterioration in the nutritional value and taste of the product as a result of direct exposure to ice crystals and dehydration of the product during freezing. For example, when storing vegetables and fruits in an ordinary low-temperature device - a refrigerator - the period of their storage is short as a result of dehydration and the mass spread of bacteria. In connection with the foregoing, the most important direction in the development of low-temperature conservation devices is the elimination of this problem using a simple, safe and reliable method.

SHORT DESCRIPTION

The aim of the present invention is to provide the device with a disinfection function in the preservation chambers, extending the preservation of stored products, preventing the loss of nutritional properties and preserving the freshness of products. Thanks to the emergence of the disinfection function, new conservation devices play a more significant role in everyday life, medicine, industry, agriculture, research and many other fields.

The Patent “Device and Method for the Production of Nanoparticles with a Negative Electric Discharge” mentions that nanoparticles with a negative electric discharge can destroy bacteria and viruses, however, their introduction into a new field - the technology of food production and low-temperature preservation - is a completely different task. First, it is necessary to explain the purpose of introducing nanoparticles with a negative electric discharge into a low-temperature conservation device and answer the question whether this will solve the problem of devices currently available on the world market. Secondly, it should be ascertained what the density of nanoparticles with a negative electric discharge in the low-temperature preservation chamber should be to achieve the effect of disinfection, sterilization and preservation of freshness of stored products, as well as what type of structural organization and operating parameters should be used for various low-temperature preservation devices to ensure their requirements for disinfection and preservation of freshness. The development of the desired low-temperature preservation device with the functions of disinfection and preservation of freshness is possible only when solving these problems. However, they were not solved in the patent "Device and method for the production of nanoparticles with negative electric discharge". At present, we are not aware of documents or procedures available in the world that are related to the introduction of technology of negative-discharge nanoparticles into low-temperature conservation devices in order to improve their productivity.

The presented invention is implemented as follows: nanoparticles with a negative electric discharge are introduced into a low-temperature preservation device made using heat-insulating materials with one or more chambers and supporting various temperatures in mobile or stationary devices, a cooling system, an electron emission unit, an electrical system, and a housing. An electron emission unit, which is an electron emitter, an emission window, a housing and various corresponding components, is provided in each low-temperature preservation chamber and is connected to the power source and the control unit by a wire. An appropriate power source and control unit are part of the electrical system.

An electron emitter in an electron emission unit is an electrode with a certain potential with respect to the ground potential outside the conservation device, emitting electrons only into the corresponding chamber of low-temperature conservation, while there are no other components with potential with respect to the ground potential outside the conservation device, except for the electron emitter inside the electron emission. An electron emitter may include one or more electrodes with the same potential. The electron emitter can be made of various materials, for example, from a metal, alloy, carbon or composite material, or other materials that support the emission of electrons. The electron emitter can have a different shape: needle, pointed, filiform, club-shaped, serrated or flat. The electron emitter can be made using various designs and sizes in accordance with the field of application and, therefore, with different potentials relative to external grounding, in the range from -2 kV to -35 kV. The electrons emitted by the emitter at the electron emission site are connected to oxygen, carbon dioxide and water molecules in the conservation chambers, to groups of these molecules or to a nanoscale molecular group, which is a combination of these molecules with other molecules in the air, so that negative electrical nanoparticles propagate in preservation chamber. Electron emission units with a different number of electrodes and units of various structures, shapes and sizes are used in accordance with the volume, shape and size of the low-temperature conservation chambers and low-temperature conservation chambers with support for the temperature range. If the density of negative electrical nanoparticles in each separate independent low-temperature preservation chamber is from 5 * 10 ³ / cm ³ to 10 ⁸ / cm ³ , the chamber operates in the disinfection mode. The low-temperature preservation chamber is filled with nanoparticles of a certain density with a negative electric discharge, and the product stored in it is surrounded by an atmosphere filled with these particles. The provided electron emission units with a different number of electrodes, of various structures and sizes meet the requirements of low-temperature conservation devices, structures, sizes and shapes of the respective chambers. An electron emitter emits electrons to form negative-discharge nanoparticles in conservation chambers; Nanoparticles with a negative electric discharge are distributed inside this chamber with a certain density and act on the surface of the stored product in the disinfection mode. In this case, the nanoparticles with a negative electric discharge are connected with water molecules on the surface of the stored product and form a hydration film while maintaining the water content in them; Nanoparticles with a negative electric discharge, adhering to the surface of the stored product, contribute to the destruction of bacteria and viruses on it. The optimal ratio of parameters and temperature, volume, structure and size of the conservation device is selected in accordance with actual requirements and scope. The refrigerant of the preservation device is designed to ensure the functioning of various special devices of low-temperature preservation with the support of various temperatures and structures that correspond to the fields of application, including the domestic sphere, sanitary processing, food industry, scientific research, industrial and agricultural production, in order to reduce energy consumption and increase the shelf life during low temperature preservation.

Compared with the prior art, the presented invention is characterized by the following advantages: providing disinfection in the low-temperature preservation chamber, reducing moisture loss of the stored product, improving the nutritional value and taste characteristics of the product, eliminating bacteria and viruses on the surface of the product. Since the three aforementioned complex effects are simultaneously realized for the low-temperature preservation chamber and for the stored product, the temperature in this chamber is no longer limited by these factors, therefore, the temperature values in the preservation chambers of various products can coincide or be increased accordingly. In addition, it is possible to choose the most suitable temperature for the actual case, which allows to reduce the energy consumption of the conservation device. An increase in temperature in the low-temperature preservation chambers makes it possible to choose a safe and cheap new refrigerant free of fluoride for the device.

Studies show that the electron emission site emitting electrons based on the tunnel effect is suitable for the existing low-temperature conservation device and can be regarded as the most suitable technology. If the density of nanoparticles with a negative electric discharge in the conservation chamber is from 5 * 10 ³ / cm ³ to 10 ⁸ / cm ³ , the chamber operates in the disinfection mode. Since nanoparticles with a negative electric discharge adhering to the surface of the preserved product have a force attracting water molecules to them on the surface of the stored product, which is a special phenomenon of hydration with the formation of a moisture film on the corresponding surface, which prevents the rapid evaporation of moisture under the influence of temperature, this allows you to retain surface moisture and at the same time helps to destroy bacteria and viruses under the influence of nanoparticles with negative elec discharge. Nodes of electron radiation with a different structure and a different number of electrodes are distributed in accordance with the volume, shape and size of the low-temperature conservation chambers, which maintains the density of nanoparticles with a negative electric discharge in the range from 5 * 10 ³ / cm ³ to 10 ⁸ / cm ³ . The energy consumption of the electron emission site is below 3 W, which is mainly due to the loss of electronic circuit elements; this value can be significantly reduced in the course of further technical improvement.

In a low-temperature conservation device with an electron emission unit, a conservation chamber can be used for disinfection; negative electric nanoparticles do not lead to environmental pollution, on the contrary, they have a beneficial effect on health. A space with a density of nanoparticles with a negative electric discharge of less than 10 ⁸ / cm ³ represents sterile disinfection conditions in which these nanoparticles combine with water molecules on the surface of the stored product and form a moisturizing film. Changes in ambient temperature do not have a significant effect on these water molecules, leading to their movement or evaporation, which ensures the preservation of the moisture level of various products with increasing temperature from 4-5 ° C to 6-9 ° C. The effect of preserving the freshness of the volume of the refrigerating chamber exceeds the analogues on the market with a storage temperature from -3 ° C to 0 ° C, while also increasing the shelf life of food products.

For example, the refrigerator freezer has two storage volumes with a temperature of -5 ° C and -12 ° C, respectively; therefore, products can be stored in volumes with different temperatures, and frozen food (including various types of meat) or products such as ice cream can be placed or stored directly in a freezer with a temperature of -5 ° C, while new products, subject to freezing, are placed in a volume with a temperature of -12 ° C. Despite the abandonment of the functions of quick and deep freezing for fresh food products stored in a sterile preservation chamber of the refrigerating space with an electronic emission unit, the surfaces of the products are sterilized during freezing, so that the effect of preserving freshness and preservation significantly exceeds the market offers.

Due to the increase in temperature in the cooling and freezing volume, the energy consumption of a refrigerator with an electron emission unit is lower than that of analogues on the market by at least 30%. In addition, as the temperature of the low-temperature cooling device rises, you can choose a new refrigerant or other low-temperature cooling device, which prevents further destruction of the ozone layer of the atmosphere under the influence of carbides.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is a cross-sectional view of a domestic refrigerator with an electron emission unit according to the present invention;

in FIG. 2 is a cross-sectional view of a low-temperature cooling transport device with an electron emission unit according to the present invention; but

in FIG. 3 is a cross-sectional view of a large-scale warehouse storage freezer with an electron emission unit according to the present invention.

DETAILED DESCRIPTION

In FIG. 1 is a cross-sectional view of a domestic refrigerator with an electron emission unit according to the present invention. Unlike the analogues on the market, the refrigeration unit proposed in the present invention is additionally equipped with an electron emission unit (2) in each of the cooling and freezing chambers. In a refrigeration unit with an electron emission unit (2), the electrons emitted by the emitter form nanoparticles with a negative electric discharge, which contribute to the destruction of bacteria and viruses in canning volumes with a distribution density of such particles of more than 5 * 10 ³ / cm ³ . Typically, the temperature in the first freezing zone (11) of the refrigerator can be from -8 ° C to -12 ° C, the temperature in the second freezing zone (12) can be -5 ° C, and the temperature in the cooling and freshness zone (13) can be from 6 ° C to 9 ° C. The refrigerator is a cooling system and an electrical system consisting of a compressor, condenser, dry filter, capillary tube, evaporator, etc. The emission window of the electron emission site occupies less than 0.2 l of space in the refrigerator with hundreds of liters of independent preservation space and is located in the corner of the preservation volume, respectively, these volumes can remain without its influence with the proper layout. As shown in FIG. 1, volumes of low-temperature storage can simultaneously be used in the form of disinfection chambers and can also be considered an exemplary implementation illustrating the implementation of a preservation and disinfection device. In addition, the temperature in each of the volumes can also vary in order to use each of them as a special disinfection chamber.

In general, the temperature in the cooling volumes of refrigeration units on the market is from 4 ° C to 5 ° C; some refrigerators have a freshness preservation zone with temperatures from -3 ° С to 0 ° С. Since refrigerators of current models do not have a sterilization function, food, vegetables and fruits can cause the spread of bacteria in storage areas, which leads to spoilage of products. Even when storing food products such as various types of meat or frozen products in a freezer at temperatures from -18 ° C to -24 ° C, they can deteriorate as a result of the multiplication of psychrophilic bacteria, including mold, while shortening the shelf life of products.

In FIG. 2 is a cross-sectional view of a low-temperature cooling transport device with an electron emission unit according to the invention. The cooling device in accordance with the present invention consists of a cooling or freezing storage volume (1), an electron emission unit (2), a cooling system, an electrical system and a power system. Since usually the volume of the low-temperature storage chamber is less than 50-80 m ³ and its maximum size is less than 6 m, equipment with only one electron emission unit is required (2). If the storage volume (1) of the refrigerator car is divided into two parts for freezing and cooling, an electron emission unit (2) can be installed in each of them. The area of the emission windows can be reduced, the set of the power supply can be used for both electron emitters of the corresponding nodes (2). The effect described above is achieved if the density of nanoparticles with a negative electric discharge in the conservation chamber (1) is from 5 * 10 ³ / cm ³ to 10 ⁸ / cm ³ .

In FIG. 3 is a cross-sectional view of a large-scale warehouse storage freezer with an electron emission unit according to the present invention. The dimensions of the cooling volume (1) are 24 m [length] * 12 m (width) * 4 m (height); eight electron emission nodes (2) are respectively located on both sides with a storage space of 12 m (a total of 16 electron emission nodes (2)), and the complete power supply unit is shared by 16 electron emission nodes (2). The area of the emission window of each such node (2) is less than 25 × 50 cm ² , and the conservation effects described above are achieved if the density of nanoparticles with a negative electric discharge in the storage volume (1) of the warehouse freezer is from 5 * 10 ³ / cm ³ to 10 ⁸ / cm ³ .

In conclusion, it should be noted that the purpose of the present invention is achieved by introducing at least one electron emission unit (2) in various configurations of a low-temperature storage chamber, a refrigerator car or a freezer storage chamber. For example, one electron emission unit (2) is placed in the refrigerator for a storage volume of max. 6 m, as well as for the volume of low-temperature storage of 50-80 m ³ ; in this case, the area of the emission window of the electron emission site (2) may be less than 25 * 50 cm ² . For a domestic electric refrigerator with a low-temperature storage space of less than 50 m ^3, the emission window area of the corresponding unit (2) and the number of electrodes of the same potential can be reduced. The electrical components of the electron emission unit (2) can be integral with the components of the low-temperature storage device. Since the volume of low-temperature storage is a disinfection space, the low-temperature conservation device can be simultaneously used as a disinfection unit or chamber, or a storage space can be used for disinfection [1]. In addition, various special disinfection storage devices are produced with functions to support various temperatures and structures that can be used in a wide variety of areas, including domestic, sanitary processing, food industry, scientific research, industrial and agricultural production, etc.

Since the volume of low-temperature storage of the invention operates in a disinfection mode, a hydration film is formed on the surface of the stored product; at the same time, nanoparticles with a negative electric discharge, adhering to the surface of the stored product, contribute to the destruction of bacteria and viruses on it. Thus, the temperature in the volume of low-temperature storage is no longer limited by these factors, which ensures the selection of the optimal combination of parameters and temperature in accordance with the volume and structure of the conservation device, actual requirements and the type of refrigeration unit of a particular storage device. First of all, the innovations of the invention touched upon existing low-temperature storage devices and were aimed mainly at reducing energy consumption, general improvement of the performance of such devices and the implementation of environmental protection measures.

Claims (9)

1. The device low-temperature preservation with the functions of disinfection and preservation of freshness, made using heat-insulating material and consisting of the following: at least one low-temperature preservation chamber with the maintenance of different temperatures in various devices of mobile and stationary types; cooling systems; electrical system; enclosures and at least one electronic emission unit installed in a low-temperature preservation chamber with maintaining various temperatures, consisting of an electron emitter, an emission window and a housing, and connected to the power source and the corresponding control unit via wires; wherein the electron emitter is an electrode with a potential with respect to the ground potential outside the conservation device, while there are no other components having a potential with respect to the ground potential outside the conservation device with the exception of the electron emitter inside electron emission; the potential of the electron emitter is from -2 kV to -35 kV; and the electron emitter consists of one or more electrodes of the same potential and is configured to emit electrons into the corresponding low-temperature preservation chamber solely on the basis of the tunnel effect. 2. The low-temperature conservation device according to claim 1, wherein the electron emitter with a sharp, sawtooth or flat characteristic is made of metal, carbon or composite material. 3. The low-temperature conservation device according to claim 1 or 2, in which the number and location of electronic emission units is determined depending on the volume, shape, size and temperature of the low-temperature conservation chamber; negative electric charge nanoparticles formed by the electron emitter based on the tunnel effect are distributed in the corresponding low-temperature conservation chamber; the density of nanoparticles with a negative electric charge in the low-temperature conservation chamber is from 5 * 10 ³ / cm ³ to 10 ⁸ / cm ³ .

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