RU2459166C2 - Grain and fodders drying and treatment installation - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: grain and fodders drying and treatment installation contains the feed and the discharge bins, a vertical drying chamber designed to be composed of 2 or more pairs of microwave heating and drying modules mounted alternately from top to bottom; the conjugated walls of the drying chambers of the microwave heating module and the dryer chamber of the drying module form a united channel for the grain flow; the cylindrical reflector and the cylindrical heat medium suction chamber positioned on the modules symmetry axis form a united heat medium suction channel covered with a conic splitter damper from above and connected to exhaust ventilation; additionally, the installation contains a microwave generator (consisting of multiple (more than 2) magnetrons with individual power supply sources), horn radiator (the apertures whereof plugged with radiotransparent plugs, oriented towards the chamber inside and installed symmetrically relative to the vertical and the horizontal axes on the heating chamber walls, each horn radiator is connected (via a standard waveguide) to the corresponding magnetron) and a blow fan; the novelty consists in the fact that the vertical drying chamber is shaped as a regular polygon within the horizontal plane, the outer diameter of the cylindrical perforated reflector being less than the heating section width by a value equal to (1.5…2.0)λ where λ is the microwave radiation wavelength.

EFFECT: installation performance increase; process energy-intensity reduction, enhancement of disinfection effect during material treatment, observation of the radiation dose during grain preplant treatment.

3 dwg

Description

The invention relates to techniques for drying grain, post-harvest and pre-sowing seed treatment, disinfection of grain materials and feed and can be used in enterprises for the production of grain, elevator and bakery industry, in livestock and poultry farming.

A known installation for drying bulk materials (RF patent No. 2201566; IPC ⁷ F26B 3/347; BI No. 9, 2003), containing a vertical drying chamber equipped with a loading and unloading devices with bunkers located in its lower part, connected to a microwave chamber generator with a communication device and a blower fan. In addition, the cavity of the blower and suction, a casing above the microwave generators with inlet and outlet nozzles, an injector with two inputs and one output, a cyclone, an air splitter with one input and two outputs are introduced into the drying chamber. The drying chamber has a rectangular shape and a tapering lower part with perforated walls with a discharge device in the form of a screw with a drive, enclosed in a casing forming a blow chamber. The loading device is made in the form of pipes with valves lowered into the drying chamber by 0.1-0.15 chamber heights and forming a suction cavity above the material. The microwave generator is made of many (more than two) low-power magnetrons with individual power sources and a communication device located evenly under the casing on the side surfaces of the drying chamber, while the casing outlet pipe above the microwave generator is connected to the fan inlet, the output of which is connected to the input of the splitter air, one outlet of which is connected to the blowing chamber; and the second - with the first inlet of the injector, the second inlet of which is connected to the air cavity above the material, and the outlet of the injector is connected to the inlet of the cyclone.

The disadvantages of this installation are the design complexity and uneven penetration of the microwave field from the periphery to the center, which leads to uneven effects on the processed product.

A known installation for drying bulk materials and a vertical drying chamber (RF patent No. 2267067; MIC ⁷ F26B 17/12, F26B 3/347; BI No. 36, 2005), containing a rectangular vertical drying chamber and a tapering lower part, microwave a generator of several (more than 2) magnetrons with individual power supplies, a blower fan, loading and unloading devices. The vertical drying chamber in this unit is functionally divided into a drying section, a heating section and a cooling section. Between the drying section and the heating section between the windows at the ends of the drying chamber there are installed horizontal U-shaped exhaust ducts of hot air, one of which is oriented along the horizontal axis of symmetry and has a horn emitter, the opening of which is plugged with a radio-transparent plug, oriented inside the drying chamber, and the radiation axis coincides with a vertical axis of symmetry of the drying chamber, horn radiators are mounted symmetrically with respect to the vertical and horizontal axis on the opposite walls of the heating section the openings of which are muffled by radiolucent plugs and oriented inside the chamber, and the radiation axes are located in the same horizontal plane, each horn emitter is connected through a standard waveguide to a corresponding magnetron, U-shaped discharge ducts of cold are installed between the heating section and the cooling section between the windows at the ends of the drying chamber air, the heating section is equipped with a supplying perforated duct connected to a nozzle for supplying hot air, the cooling section is equipped with a supplying erforirovannym duct which, via a pipe connected with the blower, each magnetron positioned in a shielded enclosure. The magnetrons are equipped with a forced air cooling system, the output of which is connected to a nozzle for supplying hot air. The adjacent horizontal microwave emitting horns have orthogonal polarizations. The walls of the drying chamber are partially perforated. The drying chamber is placed on the microwave screen. The loading and unloading devices are made in the form of conveyor belts, and in the lower tapering part of the drying chamber there is a regulator of material flow through the drying chamber. The regulator of material flow through the drying chamber is made in the form of a damper.

The disadvantages of the described installation are the unevenness of the heating zones in the flow of material, which leads to a decrease in the quality of drying and processing, relatively low efficiency and low mobility when changing dislocation.

Installation for drying bulk materials (RF patent for utility model No. 84520) was adopted as the closest technical solution in relation to the claimed. The installation for drying grain material contains loading and unloading bins, a blower fan, a rectangular rectangular drying chamber, a microwave generator from several (more than 2) magnetrons with individual power sources, horn emitters, the openings of which are plugged with radio-transparent plugs, oriented inside the chamber and are mounted symmetrically with respect to the vertical and horizontal axis on the walls of the heating chamber, and each horn radiator is connected to the corresponding to the working magnetron. The vertical drying chamber has a square section in the horizontal plane and is made in the form of structurally completed microwave heating modules and drying modules mounted alternately from top to bottom, while the mating walls of the heating and drying chambers that are part of the modules form a single grain flow channel. A cylindrical reflector and a perforated suction chamber located along the axis of symmetry of the modules form a single suction channel of the coolant, covered with a conical divider from above, and exhaust ventilation is connected from below to the channel.

The disadvantage of the described installation for drying bulk materials is the uneven distribution of the microwave field in a rectangular heating chamber, especially in its corners, which leads to a decrease in the productivity of the installation, an increase in the energy consumption of the process, a decrease in the disinfecting effect when processing the material, and non-compliance with the radiation dose during seed pre-sowing.

The objective of the proposed technical solution is to increase the productivity of the installation, reduce the energy intensity of the process, increase the disinfecting effect when processing the material, compliance with the radiation dose when presowing grain processing.

The problem is solved in that in the installation for drying and processing grain and feed, containing loading and unloading bins, a vertical drying chamber made of 2 or more pairs of microwave heating modules and drying modules mounted alternately from top to bottom, mating walls the heating chambers of the microwave heating module and the drying chambers of the drying module form a single channel of grain flow, and a cylindrical reflector and a cylindrical suction chamber of the coolant located along the axis of symmetry of the modules form a single channel of heat suction Itel, covered from above by a conical divider, and from below connected to exhaust ventilation, a microwave generator of several (more than 2) magnetrons with individual power sources, horn emitters, the openings of which are muffled by radio-transparent plugs, are oriented inside the camera and are installed symmetrically with respect to vertical and horizontal axis on the walls of the heating chamber, and each horn emitter is connected through a standard waveguide to the corresponding magnetron, the discharge fan, according to the invention in rtikalnaya drying chamber is in a horizontal plane form a regular polygon, and the outer diameter of the cylindrical perforated reflector smaller than the width of the heating chamber by an amount equal to (1,5 ... 2,0) λ, where λ - wavelength of the microwave radiation.

The invention is illustrated by drawings. Figure 1 schematically shows a General view of the inventive installation for drying grain material; figure 2 is a microwave heating module with a heating chamber in cross section, figure 3 is a drying module with a drying chamber in cross section.

The claimed installation for drying grain material (figure 1) contains a loading hopper 1; a vertical drying chamber, consisting of a pair of (2 or more) microwave heating modules 2 and drying modules 3; discharge hopper 4 with conveyor 5; a blower fan 6 and an exhaust fan 7. The microwave heating module 2 (FIG. 2) includes a microwave generators chamber 8, a heating chamber 9, in the windows of the walls 10 of which microwave-emitting horns 11 are connected through individual waveguides to magnetrons 12 with individual power sources. The openings of the microwave emitting horns 11 are muffled by radiolucent plugs 13 and oriented inward to the chamber, and the radiation axes are located in one horizontal plane. The adjacent radiating horns 11 have orthogonal polarizations. The chamber of the microwave generators 8 is formed by the outer walls 14 of the microwave heating module 2 and the walls 10 of the heating chamber 9. The walls 10 of the heating chamber 9 in a horizontal section form a regular polygon (figure 2). The heating chamber 9 is formed by the walls 10 and the walls 15 of the cylindrical reflector, the axis of symmetry of which coincides with the vertical axis of symmetry of the heating chamber 9. The drying module 3 (Fig. 3) contains a coolant supply chamber 16, a drying chamber 17 and a cylindrical coolant suction chamber 18. Supply chamber the coolant 16 is formed by the outer walls 19 of the drying module 3 and the walls 20 of the drying chamber 17. The drying chamber 17 is formed by the walls 20 and the walls 21 of the cylindrical chamber 18. The walls 20 and 21 are perforated. Structurally, the microwave heating modules 2 and the drying modules 3 are made so that the cross section of the drying module 3 is adequate to the cross section of the microwave heating module 2. The walls 10 of the heating chamber 9 and 20 of the drying chamber 17 are adequate and form a single channel for the passage of the flow of grain material connected to loading hopper, and the mating walls of the cylindrical reflector 15 and the walls 21 of the cylindrical chamber of the suction of the coolant 18 form a single channel of suction of the coolant, closed on top with a conical divider 24 (figure 1) and connected by an air duct 25 with tyazhnym fan 7. Cams 8 microwave generators 26 are connected through windows with the ducts 27 and the blower 6 through the windows 23 (Figure 2) with a coolant supply chamber 16 (Figure 3). Microwave heating modules 2 and drying modules 3, forming a vertical drying chamber, are mounted in the installation for drying grain materials alternately along the flow of grain material from top to bottom. A drying module 3 is installed behind each microwave heating module 2. The discharge hopper is equipped with a grain flow rate controller. The loading hopper is equipped with grain level sensors. Grain temperature sensors are installed in the heating chambers. Power supply, control and automation equipment can be made in the form of a device module.

Installation for drying grain material works as follows. First, the magnetron cooling system 12 and the discharge fans 6 and exhaust 7 are turned on. Then, with the shutter closed (the material flow through the drying chamber controls its outlet), the vertical drying chamber is filled with grain material (wheat, corn, sunflower seeds, etc.) through the hopper .P.). Before entering into the microwave heating module 2, the flow of grain material is evenly distributed by a conical divider 24 mounted on top of a cylindrical reflector 15. During filling, the grain material is blown with warm air and preheated. After filling the microwave heating module 2 with grain material, the magnetron power sources 12 are turned on. In the microwave heating module 2, the grain material is heated by microwave energy generated by microwave generators, each of which contains a magnetron 12 with an individual power source connected to a microwave by a standard waveguide radiating horn 11. The microwave field is reflected from the cylindrical surface of the reflector 15 and is evenly distributed inside the heating chamber. This ensures uniform heating of the material throughout the volume of the chamber 9. The temperature of the heating of the material is controlled by the on-time of the magnetrons. The temperature of the heating material in each heating chamber 9 is supported depending on the grain culture, its initial moisture content, the purpose of the grain (seed, feed, food, for technical purposes), on the required final moisture content of the material. After heating the material in the heating chamber 9 to the required temperature, open the material flow damper in the discharge hopper 4. The degree of opening of the damper depends on the required performance of the entire installation and the required final moisture content of the material.

Grain material heated by a microwave field is lowered by gravity from heating module 2 to drying module 3, where it is blown with warm air pumped by fan 6 through perforated walls 20. Air is removed through a cylindrical suction chamber of coolant 18 by fan 7.

As grain passes through the unit, it is periodically subjected to the cyclic influence of “microwave heating-convective drying”. The number of cycles is determined by the number of pairs of microwave heating and drying modules. The number of pairs of modules affects the performance of the installation.

As the material moves in the installation, its quantity in the hopper 1 decreases. According to the signal of the level sensor in the hopper 1, the material is loaded into the installation.

Warm, dried grain enters the lower drying zone 3 of the installation, where it is cooled and dried by atmospheric air. Chilled grain of the required moisture content is discharged from the installation by conveyor 5.

The proposed installation for drying and processing grain and feed has the following advantages:

- increases the productivity of the installation;

- reduced energy intensity of the process;

- increases the disinfecting effect when processing material;

- the radiation dose is observed during pre-sowing treatment of grain.

Claims (1)

Installation for drying and processing grain and feed containing loading and unloading bins, a vertical drying chamber made up of 2 or more pairs of microwave heating modules and drying modules, mounted alternately from top to bottom, while the mating walls of the heating chambers of the microwave module heating and drying chambers of the drying module form a single channel of grain flow, and a cylindrical reflector and a cylindrical coolant suction chamber located along the axis of symmetry of the modules form a single coolant suction channel, covered from above a divider, and connected from below to exhaust ventilation, a microwave generator of several (more than 2) magnetrons with individual power sources, horn emitters, the openings of which are muffled by radio-transparent plugs, are oriented inside the camera and mounted symmetrically with respect to the vertical and horizontal axes on the camera walls heating, and each horn emitter is connected through a standard waveguide to the corresponding magnetron, a discharge fan, characterized in that the vertical drying chamber s an horizontal plane in the shape of a regular polygon, and the outer diameter of the cylindrical perforated reflector smaller than the width of the heating chamber by an amount equal to (1,5 ... 2,0) λ, where λ - wavelength of the microwave radiation.

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