RU2761810C1 - Continuous-flow shf unit with ring and conical resonators for defrosting and heating of animal colostrum - Google Patents

Abstract

FIELD: agro-industrial complexes.

SUBSTANCE: invention relates to the agro-industrial complex and can be used in farms where cattle are kept, for defrosting and warming up animal colostrum. The SHF unit contains a vertically located annular resonator 1 of rectangular cross section without a lower annular base, docked with the base of the conical resonator 3, directed with its apex downward, where the ball valve 8 is installed. In the ring resonator, along the perimeter of the inner cylinder there is a slot for the electric drive 14, which ensures the movement of the compartments formed by radially located dielectric partitions 7. The base 4 of the conical resonator is perforated, with a diameter of less than a quarter of a wavelength, and air-cooled magnetrons with a shift of 120 degrees are installed on the surfaces of each resonator. On the upper base of the ring resonator, with an average perimeter that is a multiple of half the wavelength, there is a loading branch pipe 13 that performs the function of an out-of-limit waveguide, and on the outer side surface of the resonator there is an open window 9 docked with the window 11 on the side surface of the non-ferromagnetic cylinder 10 without a lower base. On the contrary, a guide dielectric strip 12 is attached to the inner side surface of the ring resonator.

EFFECT: design of the claimed invention makes it possible to separate the processes of defrosting and heating of animal colostrum, in addition to providing electromagnetic safety and high electric field strength for low-temperature disinfection of raw materials.

1 cl, 13 dwg

Description

The present invention relates to the agro-industrial complex and can be used in farms where cattle, horses, camels, goats, etc. are kept. for defrosting and warming up animal colostrum.

Colostrum residues are known to be frozen in plastic bottles to preserve the immunoglobulin and nutrients contained in the colostrum. Colostrum is thawed in defrosting machines (BMA-50, Primalakt, PM2, etc.) for feeding young animals as necessary. At the same time, the process of defrosting and heating is rather long (40-90 minutes), which makes it impossible to fully preserve the nutritional value of colostrum [1]. The principle of operation of all defrosters is based on the use of a water bath for defrosting and heating colostrum frozen in plastic bottles.

Known microwave installation (patent No. 2694944) [2] with a quasi-stationary toroidal resonator. Its disadvantages are: the frequency of loading raw materials without containers; unevenness and duration of processes and heating.

Analysis of the change in the dielectric parameters of bovine colostrum from temperature shows that the graphs describing the dielectric loss factor at negative and positive temperatures are opposite. So, the factor of dielectric loss of colostrum, at temperatures from minus 10 ° C to 0, grows from 4 to 27 [3], ie the power absorbed by the raw material during defrosting increases several times. On the contrary, when colostrum is heated from 0 to 38 ° C, the dielectric loss factor decreases, i.e. the absorbed power decreases with increasing temperature, which means the heating process is longer than the defrosting process, therefore, it is necessary to provide a different dose of EMPHW in the second resonator. Only the separation of these processes in different resonators will drastically reduce the duration of the entire technological process, and will preserve the feed value of animal colostrum.

The scientific innovative idea is that the installation should contain two resonators, providing different doses of exposure to an electromagnetic field of ultrahigh frequency (EMPHF) on colostrum, which is different in its state of aggregation. One resonator for defrosting from minus 15 ° C to 0, the other resonator for heating up to 38-40 ° C. Resonators must separate the solid and liquid phases of the raw material at a temperature equal to the phase transformation temperature.

Based on this feature, a microwave installation with two resonators (frequency 2450 MHz, wavelength 12.24 cm) has been developed, which allows defrosting and heating of frozen colostrum in plastic bottles. The absorption coefficient ( α ) of EMP by raw material depends on the wavelength and its dielectric parameters [3]:

(1)

(one)

– тангенс угла диэлектрических потерь сырья. where λ is the wavelength equal to 12.24 cm; ε is the dielectric constant of the raw material;

Is the tangent of the dielectric loss angle of the raw material.

Taking into account the empirical expressions (2, 4), describing the change in the dielectric parameters of bovine colostrum from temperature, the absorption coefficient of the EMPHF (3, 5) is:

- in the temperature range from minus 20 to 0 ^O WITH:

ε = 32.88⋅ e ^0.122⋅T , k = 27.87⋅ e ^0.21⋅T , tgδ = 0.85⋅ e ^0.082⋅T . (2)

(3)

(3)

- in the temperature range from 0 to 40 ^O WITH:

ε = 51.05⋅ e ^-0.006⋅T , k = 27.2⋅ e ^-0.021⋅T , tgδ = 0.54⋅ e ^-0.016⋅T . (4)

(5)

(5)

Uniform heating of the raw material occurs if its thickness does not exceed the depth ( γ ) of penetration of EMPWF [3]. Depth of penetration of EMPHW into raw materials

- in the temperature range from minus 20 to 0 ° С is:

(6)

(6)

- in the temperature range from 0 to 40 ^O WITH:

(7)

(7)

The graph of the dependence of the depth of penetration of EMF, with a frequency of 2450 MHz in colostrum with a fat content of 6.4% on the heating temperature, in the range from minus 10 to 0 ° C, is shown in Fig. 1. The penetration depth of a frozen raw EMPSVCH with increasing temperature from minus 12 to 0 ° C increasing from 0.14 cm to 0.93 cm. When heating colostrum from 0 ^to 40 ° C increases with the depth of penetration of 1.01 cm to 2, 17 cm.

This means that the side surface of the frozen raw material in plastic bottles is gradually thawed (Fig. 2). If the thawed liquid fraction is not removed, coagulation occurs. Therefore, as the raw material defrosts, the liquid fraction should be drained into another resonator.

The task of the invention is the development of a continuous-flow microwave installation with a ring resonator docked with the base of a conical resonator, allowing to separate the processes of defrosting and heating of animal colostrum. The installation must provide electromagnetic safety and high electric field strength for low-temperature disinfection of raw materials.

The technical result is achieved by the fact that the microwave installation of continuous-flow action with annular and conical resonators for defrosting and heating animal colostrum contains:

a vertically located annular resonator of rectangular cross section without a lower annular base, docked with the base of the conical resonator, directed with its apex downward, where the ball valve is installed,

moreover, in the ring resonator, along the perimeter of the inner cylinder there is a slot for an electric drive, which ensures the movement of the compartments formed by means of radially located dielectric partitions,

the base of the conical resonator is perforated, with a diameter less than a quarter of the wavelength, and air-cooled magnetrons with a shift of 120 degrees are installed on the surfaces of each resonator,

moreover, on the upper base of the ring resonator, with an average perimeter that is a multiple of half the wavelength, there is a loading nozzle that performs the function of an out-of-limit waveguide, and on the outer side surface of the resonator there is an open window docked with a window on the side surface of the non-ferromagnetic discharge nozzle without a lower base,

in this case, opposite the window, a guide dielectric bar is attached to the inner side surface of the ring resonator.

The essence of the invention is illustrated by graphs, research results, drawings:

fig. 1 - a graph of the dependence of the depth of penetration of EMPWF into frozen cow colostrum with a fat content of 6.4% at a temperature

minus 10 to 0 ° С b) from 0 to + 40 ° С;

fig. 2 - graph of the dependence of the penetration depth of EMPHW

into frozen bovine colostrum with a fat content of 6.4% at a temperature

from 0 to + 40 ° С;

fig. 3 - frozen colostrum in a bottle;

fig. 4 - layer-by-layer coagulation of colostrum, frozen in a bottle, in the process of defrosting in EMPHW;

fig. 5 is a schematic representation of a continuous-flow microwave installation with ring and conical resonators for defrosting and heating animal colostrum (in section);

fig. 6 is a spatial image of a continuous-flow microwave installation with annular and conical resonators for defrosting and heating animal colostrum (in section with positions);

fig. 7 is a spatial image of a continuous-flow microwave installation with ring and conical resonators for defrosting and heating animal colostrum (general view);

fig. 8 is a spatial image of a ring resonator with loading and unloading pipes;

fig. 9 is a spatial view of a ring resonator with a guide bar (bottom view);

fig. 10 is a perspective view of dielectric compartments formed from partitions (front view);

fig. 11 is a spatial view of compartments with guiding assemblies for an electric drive (top view);

fig. 12 is a spatial view of the perforated non-ferromagnetic base of the conical resonator;

fig. 13 is a perspective view of a conical resonator on a mounting frame.

A continuous-flow microwave installation with ring and conical resonators for defrosting and heating animal colostrum contains:

an annular resonator of rectangular cross-section without a lower base 1;

magnetrons 2 on the outer side surface of the ring resonator;

a conical resonator 3 with a base 4 having a perforation 5;

magnetrons 6 on the surface of the conical resonator;

dielectric partitions 7, forming the compartments;

ball valve 8 at the top of the conical resonator;

an open window 9 on the outer side surface of the ring resonator; non-ferromagnetic discharge pipe 10 without base;

an open window 11 on the side surface of the non-ferromagnetic discharge pipe; dielectric guide bar 12;

loading branch pipe 13; electric drive 14 for movement of compartments.

A ring resonator 1 with magnetrons 2 is formed between two coaxially located non-ferromagnetic cylinders (outer and inner), an upper annular non-ferromagnetic base and a non-ferromagnetic perforated base 4, which is simultaneously the base of a conical resonator 3 directed with its top down and docked to the ring resonator. Some magnetrons 2 with a shift of 120 degrees are located on the side surface of the ring resonator, other magnetrons 6 are also with a shift of 120 degrees located on the surface of the conical resonator, closer to the base. Above the perforated base 4, inside the annular volume, dielectric partitions 7 are radially installed, forming compartments. The average perimeter of the ring volume of the resonator is a multiple of half the wavelength. The base is perforated 5, with a diameter of no more than a quarter of the wavelength. At the top of the conical resonator there is a ball valve 8. On the side surface of the ring resonator there is an open window 9. A non-ferromagnetic discharge nozzle 10 without a base and with an open window 11 on the side surface is docked to the window. These windows are docked and form an opening. Opposite the opening, a dielectric guide bar 12 is attached to the side surface of the inner cylinder of the ring resonator. On the upper ring base of the resonator, there is a loading branch pipe 13, which performs the function of an out-of-band waveguide, with a diameter not less than the diameter of a dielectric bottle with raw materials. Moreover, this pipe is located in front of the open window 9 on the side surface of the ring resonator 1. The compartments are moved in the annular volume using an electric drive 14 mounted on the guide platform. Between the inner cylinder of the ring resonator and the perforated base 4 there is a slot for moving the assembly connecting the shaft of the electric drive 14 with the radial dielectric partitions 7. A thermocouple is located next to the ball valve, this is possible due to the fact that the conical resonators, closer to the top, have a critical section, beyond which there is no EHMSVCH.

The technological process of defrosting and warming up animal colostrum in a continuous-flow microwave installation with ring and conical resonators is as follows. Turn on the electric drive 14 to move the compartments in the annular resonator volume 1. Load dielectric bottles without a lid with frozen raw materials into the loading nozzle 13, having previously closed the ball valve 8. Turn on the magnetrons 2, the emitters of which are directed to the annular resonator 1. In the process of moving the compartments, load through transcendental waveguide regular bottles with frozen raw materials, without caps. An EMF of a traveling wave is excited in the ring resonator, and in accordance with the depth of penetration of the electromagnetic field, the frozen raw material is defrosted layer by layer, flows through the holes 5 of the perforation of the base 4, into the second resonator 3. Turn on the magnetrons 6, the emitters of which are directed into the conical resonator 3. Moreover, bottles with raw materials move in the annular space and are emptied at the end of a full turnover of the compartments, as defrosting occurs under the influence of dielectric heating. An empty bottle at the end of a complete turnover of the compartments abuts against the dielectric bar 12, and is pushed into the non-ferromagnetic discharge pipe 10 without a base, through the opening formed by the docked open windows 9, 11, falls into the container for collecting empty bottles. The liquid raw material is accumulated in the conical resonator 3, is exposed to the EMPWCH, is heated to 38-40 ° C and, through the ball valve 8, is dosed into the receiving container. The raw material temperature is controlled by a temperature sensor (thermocouple). An electric field of high intensity is excited in both resonators, sufficient to reduce the bacterial contamination of the product.

Sources of information

1. Colostrum defroster // Colostrum defroster "PrimaLakt" Operation manual [Electronic resource]. URL: propribory.ru › static / upl / 27-03-2020 / OskNzivotnovodstvo.ru › molozivo-ego-sostav-svojstva… i… (date of access 03.13.2021).

2. Patent No. 2694944 RF, IPC А47J.39 / 00. Microwave installation for defrosting cow colostrum / G. V. Novikova, D. V. Poruchikov, A. N. Vasiliev, I. G. Ershova, M. V. Belova; applicant and patentee FGBNU "FNATS VIM" (RU). - No. 2018143727; declared 11.12. 2018. Bul. No. 20 dated 07/18/2019.

3. Rogov, I.A. Electrophysical, optical and acoustic characteristics of food products / I.A. Rogov. - M .: Light and food industry, 1981. - 288 p.

Claims (1)

A continuous-flow microwave installation with annular and conical resonators for defrosting and heating animal colostrum contains a vertically located annular resonator of rectangular cross section without a lower annular base, docked with the base of the conical resonator, directed downward, where the ball valve is installed, and in the annular resonator, along the perimeter of the inner cylinder has a slot for an electric drive, which ensures the movement of the compartments formed by radially located dielectric partitions, while the base of the conical resonator is perforated, with a diameter of less than a quarter of a wavelength, and air-cooled magnetrons with a shift of 120 degrees are installed on the surfaces of each resonator, and on the upper base of the ring resonator, with an average perimeter that is a multiple of half the wavelength, there is a loading branch pipe that performs the function of a transient waveguide, and on the outer side surface of the resonator there is There is an open window docked with the window on the side surface of the non-ferromagnetic discharge nozzle without a lower base, while a dielectric guide bar is attached opposite the window to the inner side surface of the ring resonator.

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