BR122020013962A2 - DEVICE FOR HEATING A MATERIAL THROUGH MICROWAVES, SYSTEM FOR HEATING A MATERIAL THROUGH MICROWAVES, AND METHOD FOR HEATING A MATERIAL THROUGH MICROWAVES - Google Patents

Abstract

"DEVICE FOR HEATING A MATERIAL THROUGH MICROWAVES, SYSTEM FOR HEATING A MATERIAL THROUGH MICROWAVES, AND METHOD FOR HEATING A MATERIAL THROUGH MICROWAVES". The present invention relates to a device for heating materials using microwaves, particularly applicable to the heating of ore products, which makes it possible to eliminate the use of fossil fuels (for example natural gas, coal, heavy oil etc.) for heat generation for heating this type of material, enabling the use of microwaves for heating materials through a more efficient dispersion of its electromagnetic waves. The present invention also relates to a system that makes use of a heating chamber, and a microwave heating method.

Description

[001] Division of patent application BR102020012185-5 filed on 06/17/2020.

[002] The present invention relates to a device for heating materials by microwave, particularly applicable to the heating of ore products, which allows to eliminate the use of fossil fuels (for example natural gas, coal, heavy oil etc. .) for the generation of heat for heating this type of material, enabling the use of microwaves for heating materials through a more efficient dispersion of its electromagnetic waves.

[003] The present invention also relates to a system that makes use of a heating chamber, and a microwave heating method.

Description of the State of the Art

[004] In many cases, the process of reducing mining product moisture by heating this product is extremely harmful to the environment, since, as it is currently exploited by the mining industry, it is necessary to use kilns based on fossil fuels (eg natural gas, coal, heavy oil etc.).

[005] In order to reduce the environmental impacts caused by the use of such technology by the emission of CO2, the development of alternative methods of reducing the humidity of the mining product has been promoted.

[006] Amid the solutions proposed in the state of the art, the use of systems to reduce the humidity of mining products by means of microwave radiation has aroused the interest of different sectors in the mining area.

[007] However, problems related to performance imply costs of implementation and large-scale operation of this type of solution and prevent its use from becoming more economically advantageous. For example, in a simpler solution, where the mining product is heated by being subjected only to electromagnetic waves, the time required to heat the product and the cost of equipment are factors that hinder the use of technology on a large scale. This is because, after studies and analyzes conducted on the energy use of these devices, it was observed that the electromagnetic waves are not properly dispersed in the regions of interest of the ore products.

[008] It was observed that the heating is carried out in a very heterogeneous way, which greatly impairs the efficiency of the heating process of the material. Ideally, heating should take place more evenly across the material's surface. Instead, the lack of dispersion observed in the state of the art drying devices implies a longer exposure time to achieve an adequate drying of the product and makes the process inefficient and with non-competitive operating costs.

[009] This is mainly due to an inherent design flaw in state of the art microwave heaters. When using a single chamber with multiple wave emitting sources, an electromagnetic wave from a first source may enter the output of a second source, which may burn your magnetron. To avoid this situation, it is necessary to resort to a greater distance between the sources increasing the size of the chamber, which, in turn, decreases the power x area ratio (KW / m2). In addition, the emission of electromagnetic waves directly in the empty space inside the chamber does not allow an adequate reflection and dispersion of them for a homogeneous heating of the material of interest, which further reduces the efficiency of the device.

[0010] The state of the art brings some possibilities for building chambers for microwave heating, as can be seen in the US patent document US4870236. This document proposes a chamber for heating materials by microwave that makes use of at least one pair of cavities in which the source of electromagnetic waves is available. The waves are reflected inside the waveguide to eventually reach the main chamber where the materials to be heated are located. However, this solution shown in document US4870236 does not solve the problem of inefficient dispersion of electromagnetic waves, since the waves are distributed uncontrollably after arriving in the chamber, which results in the same heterogeneous dispersion observed in the other chambers of the prior art.

[0011] Therefore, it is not observed in the state of the art a microwave heating device that is capable of dispersing the electromagnetic waves properly, resulting in an efficient heating of the mining product and allowing the elimination of the use of obtaining heat through combustion, which are harmful to the environment as well as a reduction in electricity and fossil fuels.

Objectives of the Invention

[0012] A first objective of the present invention is to provide a microwave heating device that allows to replace and eliminate completely or partially the need to use fuel burning systems to obtain heat.

[0013] A second objective of the present invention is to provide a microwave heating device that allows the efficient and homogeneous dispersion of the electromagnetic waves on the product to be heated.

[0014] A third objective of the present invention is to provide a microwave heating device provided with a main cavity and an auxiliary cavity for the dispersion of electromagnetic waves efficiently.

[0015] A fourth objective of the present invention is to provide a microwave heating system that makes use of the heating chamber to allow efficient and serial heating of the material of interest

[0016] A fifth objective of the present invention is to provide a microwave heating method that makes use of the aforementioned heating device.

Brief Description of the Invention

[0017] The present invention deals with a device of the present invention comprising a main cavity defining an inner portion and an outer portion of the device, the main cavity being configured to receive at least one source of electromagnetic wave emission, the device comprising at least an auxiliary cavity arranged inside the main cavity and in the middle between the source and the outer portion, the auxiliary cavity delimiting an auxiliary reflection region of at least part of the electromagnetic waves generated by the source.

[0018] In a possible configuration, the auxiliary cavity has a rectangular cross-section whose walls project from a pair of side walls of the housing, parallel to a vertical center line of reference of the cavity and towards the outer portion.

[0019] In another possible configuration, each side wall comprises at least a portion inclined at an acute angle formed in relation to the vertical centerline.

[0020] In another possible configuration, the angle of inclination of the inclined portion of the main cavity wall is between 15 ° to 40 °.

[0021] In another possible configuration, at least one wall of the main cavity has a permanent magnet element.

[0022] The present invention also deals with a method of heating a material by microwave which makes use of a device comprising a main cavity defining an inner portion and an outer portion of the device, the main cavity being provided with at least one wall, and being configured to receive at least one source of electromagnetic wave emission, the method comprising the step of:

[0023] - reflect at least part of the electromagnetic waves emitted by the source in at least a portion of an auxiliary cavity arranged inside the main cavity and in the middle between the source and the external portion.

[0024] In a possible configuration, the method comprises at least one of the steps of:

[0025] - reflect at least part of the electromagnetic waves emitted by the source in at least a portion of the wall inclined at an acute angle formed in relation to a vertical center line of reference of the main cavity;

[0026] - change the course of at least part of the electromagnetic waves emitted by the source through a permanent magnet element arranged in at least one wall of the main cavity.

[0027] The present invention also deals with a system for heating a material by microwave which comprises a material conveyor to be heated and a material feeding zone on the conveyor, the system comprising a material heating zone, the material feeding zone being arranged prior to the material heating zone, the material heating zone comprising at least one microwave heating chamber provided with at least one microwave heating device such as the one mentioned above.

[0028] In a possible embodiment, the system comprises plates of dielectric material arranged on the conveyor and a plate heating zone, the material feeding zone being arranged in the middle between the plate heating zone and the heating zone of material, the plate heating zone comprising at least one microwave heating chamber provided with at least one microwave heating device such as the above.

Brief Description of Drawings

[0029] The present invention will be described in more detail below based on an example of execution shown in the drawings. The figures show:

[0030] Figure 1 - is a side view of a state-of-the-art microwave material heating chamber without cavities;

[0031] Figure 2 - is a top view of a state-of-the-art microwave material heating chamber without cavities;

[0032] Figure 3 - is an image of the lower region of a state-of-the-art microwave material heating chamber separated into two cavities by a wall, including a temperature gradient image of the heated surface;

[0033] Figure 4 - is a side view of a completely rectangular cavity of the state of the art;

[0034] Figure 5 - is a top view of a completely rectangular cavity of the state of the art;

[0035] Figure 6 - is a side view of a state-of-the-art microwave material heating chamber with completely rectangular cavities;

[0036] Figure 7 - is a schematic representation of the behavior of electromagnetic waves in a state of the art material microwave heating chamber with completely rectangular cavities, including a temperature gradient image of the heated surface;

[0037] Figure 8 - is a side view of a first embodiment of the device of the present invention;

[0038] Figure 9 - is a top view of a first embodiment of the device of the present invention;

[0039] Figure 10 - is a temperature gradient image of the heated surface when using the device of the present invention in its first embodiment;

[0040] Figure 11 - is a side view of a second embodiment of the device of the present invention;

[0041] Figure 12 - is a top view of a second embodiment of the device of the present invention;

[0042] Figure 13 - is a schematic representation of the behavior of electromagnetic waves when using the device of the present invention in its second embodiment, including a temperature gradient image of the heated surface;

[0043] Figure 14 - is a side view of the heating chamber of the present invention in a preferred configuration;

[0044] Figure 15 - is a side view of the heating system of the present invention in a preferred configuration; and

[0045] Figure 16 - is a detail of the side view of the heating system of the present invention in a preferred configuration.

Detailed Description of the Figures

[0046] Figures 1 and 2 reveal a chamber 100 'for heating material by microwave of the state of the art. This chamber 100 'comprises side walls 110' and an upper wall 120 'forming a simple rectangle with inner portion 2' and outer portion 3 ', the inner portion 2' housing multiple sources 30 'emitting electromagnetic waves which heat the material disposed below of the chamber 100 'in its outer portion 3'. Figure 3 shows an image of the lower region of a state-of-the-art microwave material heating chamber 100 'separated into two cavities 10A', 10B 'by a wall, including a temperature gradient image of the heated surface corresponding to both sides 11 A ', 11B' of the chamber.

[0047] It is observed that, in this embodiment of figures 1 to 2, no type of cavity is used, which exposes the sources 30 'to each other's electromagnetic waves and can cause the burning of their magnetrons. clarified, to avoid this burning, the sources 30 'of this previous embodiment need to be spaced apart at a great distance, which reduces the power x area ratio (KW / m2) and impairs the correct dispersion of the electromagnetic waves, as can be best seen in figure 3. In a brief comparison, state-of-the-art heating chambers 100 'use distances between sources three to four times greater than those allowed by the present invention, as will become clear below. Although a wall is used to separate the cavities, as seen in figure 3, the result is not satisfactory.

[0048] Figures 4 to 7 show a cavity 10 'of the prior art, figure 6 being a representation of this cavity 10' applied to a chamber 100 'of the prior art. It is observed that this previous embodiment tries to eliminate the possibility of burning the sources 30 'by inserting them in cavities 10', as well as trying to direct the electromagnetic waves derived from the source 30 'towards the material to be heated.

[0049] However, figure 7 reveals a schematic representation of tests performed in these state of the art 10 'microwave heating cavities, where V1' is a side view of the device revealing the wave lines reflected on the surface of its structure - height, V2 'is a top view of the device for reference, and V3' is an image revealing the temperature gradient of the heated surface, where the warmer colors represent higher temperatures and the colder, lower temperatures. Again, it was observed that the heating is carried out in a heterogeneous way and the center of the surface does not appreciate almost any heating, which proves the lack of efficiency in the dispersion of the waves even though using this type of cavity 10 ’.

[0050] Thus, the state of the art is not able to offer a device, chamber or system for heating materials by microwave that is sufficiently efficient to replace the use of heat generation by burning fuel.

[0051] To solve this problem, a device 1 of the present invention is provided in a first embodiment shown in figures 8 to 10; in a second embodiment shown in figures 11 and 13, a chamber 100 that makes use of these embodiments of the device 1 in figure 14, and a system 200 that makes use of chamber 100.

[0052] In a first embodiment of the device 1 of the present invention shown in figures 8 to 10, a device 1 is provided provided with a cavity 10 whose wall format is conducive to the dispersion of the electromagnetic waves efficiently on the product to be heated.

[0053] More specifically, the device 1 in its first embodiment comprises a main cavity 10 defining an inner portion 2 and an outer portion 3 of the device 1 and being provided with at least one wall 11. The main cavity 10 is configured to receive the at least one source 30 of electromagnetic wave emission, which emits, preferably, electromagnetic waves with wavelength between 122 mm and 328 mm and frequency in the range between 2450 and 915 MHz, this interval being able to vary substantially according to the desired application.

[0054] In this first embodiment, at least one wall 11 of the main cavity 10 comprises at least a portion inclined at an acute angle T formed in relation to a vertical center line Y of reference of the main cavity 1. The housing preferably also comprises , an upper wall 12 housing the fountain 30, more preferably arranged perpendicular to the centerline Y.

[0055] The Y centerline is an imaginary guideline that vertically cuts the housing 10 from its center in a side view in a mirrored split arrangement. Each side wall 11 projects at an acute angle T in relation to this centerline Y, in a direction away from the centerline Y, so that the housing 10 forms a substantially conical shape or a “bi-pyramidal horn ”. The angle T is preferably between 15 ° and 40 °, more preferably between 20 ° and 30 °, and more referentially 28 °. More preferably, the device 1 of the present invention may comprise two pairs of side walls 11 arranged perpendicularly to each other two by two, forming a substantially pyramidal shape.

[0056] The use of a main cavity 10 provided with a side wall 11 with an acute T angle of inclination allows a more efficient reflection of the electromagnetic waves emitted by the source 30 in the direction of dispersion of the waves on the material to be heated. In this way, a homogeneous temperature gradient is obtained, as seen in figure 10.

[0057] In this way, a more efficient dispersion level is obtained through this first embodiment than that seen in the state of the art chambers and cavities, increasing the power x area ratio (KW / m2) and enabling its application, for example , in the context of heating ore products, which is made clear by the simple comparison between figures 3 or 7 and figure 10.

[0058] In accordance with this first embodiment of device 1, a method of heating material by microwave is also provided, comprising the step of:

[0059] - reflect at least part of the electromagnetic waves emitted by the source 30 in at least a portion of the wall 11 inclined at an acute angle T formed in relation to a vertical center line Y of reference of the main cavity 1.

[0060] A second embodiment of the present invention can be seen in figures 11 to 13, where a main cavity and an auxiliary cavity are used to efficiently disperse electromagnetic waves. In this second embodiment there is a main cavity 10 defining an inner portion 2 and an outer portion 3 of the device 1, the main cavity 10 being configured to receive at least one source 30 of electromagnetic wave emission, as seen also in the first concretization.

[0061] In this second embodiment, device 1 comprises at least one auxiliary cavity 20 disposed within the main cavity 10 and in the middle between the source 30 and the outer portion 3. The auxiliary cavity 20 delimits an auxiliary reflection region 6 of steel less part of the electromagnetic waves generated by the source 30 to allow an additional reflection of said waves and to ensure a greater dispersion of them over the material to be heated.

[0062] The auxiliary cavity 20 preferably comprises a rectangular cross-section whose walls 21 project from a pair of side walls 11 of the housing, parallel to a vertical center line Y of the cavity 10 and towards the portion exterior 3, configuring a substantially “cube” or “box” shape. The side walls 11 of the housing can be angled or not, configuring a “bi-pyramidal horn” shape or others, such as simply rectangular or square.

[0063] The upper and lower surfaces of the auxiliary cavity 20 are opened for the passage of the electromagnetic waves provided by the source 30. Other cross profiles can be used to construct the auxiliary cavity 20, depending, for example, on the shape of the main cavity 10, the type of material to be heated or the desired application.

[0064] The auxiliary region 6 for reflecting electromagnetic waves is bounded by the walls of the chamber 20 and its upper and lower openings. This region 6 aims to reflect the electromagnetic waves in a pattern that disperses them in a region of interest. In this way, a homogeneous heating of the material is obtained.

[0065] In accordance with the second embodiment of device 1 disclosed above, a method for microwave material heating is provided, comprising the step of:

[0066] - reflect at least part of the electromagnetic waves emitted by the source 30 in at least a portion of an auxiliary cavity 20 disposed inside the main cavity 10 and in the middle between the source 30 and the external portion 3.

[0067] Having presented the first and the second embodiment of the device 1 of the present invention, a third possible embodiment involves joining the first and second embodiments to obtain a device 1 of particular efficiency, thus joining the characteristics of wall format 11 and of auxiliary cavity 20 to promote an even more homogeneous and efficient dispersion of electromagnetic waves.

[0068] Figures 11 to 13 reveal this third embodiment, providing for the use of walls 11 provided with an angle T in relation to the vertical axis Y of reference, as well as the existence of an auxiliary cavity 20 inside the main cavity 10. Observe the effects of this third embodiment are shown in figure 13, which shows the temperature gradient in a product heated by the device 10 of figures 11 to 13. More specifically, figure 13 reveals images V1 and V2, where V1 is a side view of the device 1 of the present invention revealing the wave lines reflected on the surface of its main cavity 10 and its auxiliary cavity 20, and V2 is an image revealing the temperature gradient of the surface heated by the device 1 of the present invention, where the warmer colors represent greater temperature and the colder, lower temperature. There is an advantageously homogeneous heating result, proving the adequate efficiency of this third embodiment in the heating of materials through microwaves, and proving to be a viable alternative to heating by burning fuel.

[0069] In accordance with this third embodiment of the present invention, it is clarified that the methods linked to the first and second embodiments can be combined in a single method for particularly efficient heating of a material by microwave, which comprises the steps in:

[0070] - reflect at least part of the electromagnetic waves emitted by the source 30 in at least a portion of the wall 11 inclined at an acute angle T formed in relation to a vertical center line Y of reference of the main cavity 1; and

[0071] - reflect at least part of the electromagnetic waves emitted by the source 30 in at least a portion of an auxiliary cavity 20 disposed inside the main cavity 10 and in the middle between the source 30 and the external portion 3.

[0072] Presented three possible embodiments of device 1 of the present invention, below are features of device 1 that can be applied to any of the embodiments, optionally, to obtain different beneficial effects on their functionality and use.

[0073] Optionally and applicable in any of the aforementioned embodiments, device 1 may comprise, on at least one wall of the main cavity 10, a permanent magnet element 22, for example, composed of ferrite or neodymium. This magnet 22 aims to change the course of at least part of the electromagnetic waves, specifically the magnetic waves, emitted by the source 30, in order to complement the dispersion of the waves on the product of interest. The magnet 22 can, for example, be arranged on the inclined portions of the walls 11 of the device 1, and at different heights to obtain different effects of altering the electromagnetic wave course depending on the desired application.

[0074] For a better understanding of the effects of including the magnet in device 1 of the present invention, it is clarified that the electromagnetic waves that are constituted by electric waves and magnetic waves, which propagate orthogonally. When the magnet is applied to device 1 of the present invention, the magnetic pole at the north pole is attracted by the magnet at the south pole, up to the direction of the wall, reflecting and changing the trajectory of the magnetic wave. The south pole wave is attracted by the north pole magnet, reflecting and changing the trajectory of the magnetic wave.

[0075] Accordingly, any of the aforementioned methods can also comprise a stage of:

[0076] - change the course of at least part of the electromagnetic waves emitted by the source 30 through a permanent magnet element 22 disposed in at least one wall of the main cavity 10.

[0077] Each embodiment the device 1 cited here may also comprise a projection 13 arranged in the lower portion of its or its walls 11 and, preferably, projected parallel to the vertical reference line Y, more preferably involving the entire perimeter of the main cavity 10, such as a “skirt”. This projection 13 is intended to prevent electromagnetic waves from exiting the perimeter of the cavity

[0078] Thus, the device 1 of the present invention in its embodiments shown here is capable of efficiently dispersing the electromagnetic waves emitted by the source 30, either by its reflection of the inclined walls of the main cavity 10, or by its reflection in the cavity auxiliary 20, thus allowing homogeneous heating of the material of interest and ensuring the viability of using electromagnetic waves for heating / drying products. In particular, the device 1 of the present invention is advantageously applicable to chambers for heating / drying ore products, since they allow to replace the use of heat generators by burning fuels such as coal, natural gas and heavy oil, bringing relevant advantages from an ecological point of view.

Accordingly, the present invention also relates to a chamber 100 for microwave material heating which comprises a device such as the aforementioned in any of its embodiments. As can be seen in figure 14, the chamber 100 can, for example, be composed of side walls 110 and an upper wall 120, the lower portion having open for the passage of electromagnetic waves. Within the walls 110, 120, there is at least one device 1 such as the one mentioned above in any of its embodiments, and preferably multiple devices 1 arranged in series. The number of devices 1 inserted in the chamber 100 depends on various factors such as the material to be heated, the required temperature for final heating of the product, etc.

[0080] Additionally, the present invention also relates to a system 200 for heating material by microwave which comprises a chamber 100 such as the one mentioned above. The system 200 is illustrated in a preferred configuration, but not mandatory, in figures 15 and 16, where it can be seen that it comprises a conveyor 201 of material M to be heated and a material feeding zone B on the conveyor 201. The system further comprises a material heating zone A, the material supply zone B is arranged anteriorly to the material heating zone A, where the material heating zone A comprising at least one chamber 100 such as the aforementioned .

[0081] Optionally, system 200 comprises plates of dielectric material 202 (i.e., plates of material with high dielectric property) arranged on conveyor 201 and a heating zone of plate C, where the material feeding zone B it is arranged in the middle between the plate heating zone C and the material heating zone A. Furthermore, the plate heating zone C comprises at least one chamber 100 such as the one mentioned above.

[0082] Preferably, but not mandatory, conveyor 201 is a grid carrier, and the plate of dielectric material 202 is composed of refractory material with high dielectric property, which may, for example, be silicon carbide, dioxide compounds manganese (MnO2) or (CaMn7O12), or even Barium Titanate.

[0083] Having described a preferred embodiment example, it should be understood that the scope of the present invention covers other possible variations, being limited only by the content of the appended claims, including the possible equivalents therein.

Claims (10)

1. Device (1) for heating a material through a microwave comprising a main cavity (10) defining an inner portion (2) and an outer portion (3) of the device (1), the main cavity (10) being configured to receive at least one source (30) of electromagnetic wave emission, the device (1) being characterized by the fact that it comprises at least one auxiliary cavity (20) disposed inside the main cavity (10) and in the middle between the source (30) and the outer portion (3), the auxiliary cavity (20) delimiting an auxiliary region (6) for reflection of at least part of the electromagnetic waves generated by the source (30). 2. Device (1) for heating a material using a microwave, according to claim 1, characterized by the fact that the auxiliary cavity (20) has a rectangular cross-section whose walls (21) protrude from a pair of side walls (11) of the housing, parallel to a vertical center line (Y) of the cavity reference (10) and towards the outer portion (3). 3. Device (1) for heating a material by microwave, according to claim 1, characterized by the fact that each side wall (11) comprises at least a portion inclined at an acute angle (T) formed in relation to the vertical centerline (Y). 4. Device (1) for heating a material by microwave, according to claim 3, characterized by the fact that characterized by the fact that the angle (T) is between 15 ° and 40 °. 5. Device (1) for heating a material by microwave, according to claim 1, characterized by the fact that at least one wall of the main cavity (10) has a permanent magnet element (22) . 6. Method of heating a material by microwave, the method using a device (1) comprising a main cavity (10) defining an inner portion (2) and an outer portion (3) of the device (1), the main cavity (10) being provided with at least one wall (11), the main cavity (10) being configured to receive at least one source (30) of electromagnetic wave emission, the method being characterized by the fact that it comprises the step: - reflect at least part of the electromagnetic waves emitted by the source (30) in at least a portion of an auxiliary cavity (20) arranged inside the main cavity (10) and in the middle between the source (30) and the portion exterior (3). 7. Method of heating a material by microwave, according to claim 6, characterized by the fact that it comprises the step of: - reflecting at least part of the electromagnetic waves emitted by the source (30) in at least a portion of the wall (11) inclined at an acute angle (T) formed in relation to a vertical center line (Y) of reference of the main cavity (10). 8. Method of heating a material by microwave, according to claim 6, characterized by the fact that it comprises the step of: - changing the course of at least part of the electromagnetic waves emitted by the source (30) through a permanent magnet element (22) arranged on at least one wall of the main cavity (10). 9. Microwave heating system (200) for a material (M) comprising a material conveyor (201) to be heated and a material feeding area (B) on the conveyor (201), the system (200) being characterized by the fact that it comprises a material heating zone (A), the material feeding zone (B) being arranged before the material heating zone (A), the material heating zone (A) comprising at least one microwave heating chamber (100) provided with at least one microwave heating device (1) as defined in claim 1. 10. Microwave heating system (200) of a material (M) according to claim 9, characterized by the fact that it comprises plates of dielectric material (202) arranged on the conveyor (201), the system ( 200) comprising a plate heating zone (C), the material feeding zone (B) being arranged in the middle between the plate heating zone (C) and the material heating zone (A), the heating plate (C) comprising at least one microwave heating chamber (100) provided with at least one microwave heating device (1) as defined in claim 1

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