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In comparison to conventional heating methods, microwave processing has an inherit benefit of increased efficiency. By transferring energy via electromagnetic waves, heat transfer is not limited to only particles on the surface of a material, improving the rate of energy transfer in comparison to conventional heating. As energy is transferred using electromagnetic waves ability to penetrate surface layers, a new temperature profile exist for microwave processing, As heating is no longer dependent upon surface area, and is now dependent upon volume. In contrast to conventional heating, microwave processing has an inverse heating scheme. As electromagnetic penetrate the material, heating is modeled relative to the volume of material absorbing energy. | In comparison to conventional heating methods, microwave processing has an inherit benefit of increased efficiency. By transferring energy via electromagnetic waves, heat transfer is not limited to only particles on the surface of a material, improving the rate of energy transfer in comparison to conventional heating. As energy is transferred using electromagnetic waves ability to penetrate surface layers, a new temperature profile exist for microwave processing, As heating is no longer dependent upon surface area, and is now dependent upon volume. In contrast to conventional heating, microwave processing has an inverse heating scheme. As electromagnetic penetrate the material, heating is modeled relative to the volume of material absorbing energy. | ||
=== | ===Dielectric Properties=== | ||
The interaction of electromagnetic radiation with materials, causing heat transfer is understood to work via the mechanisms of conduction and polarization. The electromagnetic wave causes movement, or rotation of dipoles, adding energy to a material. | |||
Dielectric properties of materials vary in accordance to there molecular structure, atomic bond strength and type. Research into dielectric properties is still lacking, ,and corresponding relationship's have failed to accurately predict the precise properties of material's dielectric permissibility. Although, the interaction between microwaves and materials is understood, this is thought to be relative to factors,such as structure and bond type having significant effects upon the permissibility . The dielectric properties, effect the absorbency and reflection coefficients of materials, causing a variety of problems, from the low penetration of electromagnetic waves to frequency transparency. | |||
===Absorption=== | ===Absorption=== | ||
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Temperature – During the heating of materials it is seen the rate of absorption increases with temperature. It is noted that this property leads to an acceleration in heat transfer, in high temperature heating, causing processing issues, such as runaway, where temperature changes faster then initially planed for a process. | Temperature – During the heating of materials it is seen the rate of absorption increases with temperature. It is noted that this property leads to an acceleration in heat transfer, in high temperature heating, causing processing issues, such as runaway, where temperature changes faster then initially planed for a process. | ||
Penetration Depth - Dependent upon frequency and dieletric properties, depth affects where the heat is transferred to. In a convection oven, heat is transferred by infared frequency radiation, and conduction occurs across the surface area. | |||
===Reflection=== | ===Reflection=== | ||
When a wave is incident, to a surface plane, i.e. passing from air to a solid. A portion of the incident wave will be reflected by the surface. | |||
Using the principal of reflection efficiency of a microwave heating can be increased. Through the use of a reflective metal cavity, the bouncing of electromagnetic radiation through a material can greatly increase absorption. A given wave will effectively pass through a sample multiple times increasing the electromagnetic field strength. Constructive interference between electromagnetic waves, will produces greater field strengths, using a frequency near the resignation frequency of the resonator is there fore ideal. Use of resonating arrangement is applicable to both high and low loss materials. | Using the principal of reflection efficiency of a microwave heating can be increased. Through the use of a reflective metal cavity, the bouncing of electromagnetic radiation through a material can greatly increase absorption. A given wave will effectively pass through a sample multiple times increasing the electromagnetic field strength. Constructive interference between electromagnetic waves, will produces greater field strengths, using a frequency near the resignation frequency of the resonator is there fore ideal. Use of resonating arrangement is applicable to both high and low loss materials. | ||
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===Joining=== | ===Joining=== | ||
===Polymer Curing=== | ===Polymer Curing=== | ||
===Plasma Processing=== | ===Plasma Processing=== | ||
===Post Fabrication Processing=== | ===Post Fabrication Processing=== | ||
== References == | == References == | ||
<layout name="Howtos" /> | <layout name="Howtos" /> | ||
Revision as of 05:51, 14 November 2008
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This page is part of a project for MECH370, a Queen's University class on materials processing. Please do not edit this page before Dec. 1, 2008 unless you are in that class, but feel free to make comments using the discussion tab. |
This page is under construction
Introduction
Microwave processing, is not a new idea, however has not been implemented in large scales by industry until recent years. Since the 1940's microwaves have been implemented in food processing sectors. However microwave processing is only starting to gain strength in the industrial sector. Improvements in the understanding of microwave absorption properties, and new techniques for improving absorption are opening up new fields of application for a relatively old technology. Recent advances, have presented the world with continuous microwave systems for commercialization, the ability to sinter powdered metals, and transparent ceramics.
Thermo Physical Properties of Microwave Heating
Heating of a material using electromagnetic energy is based on a material capacity to efficiently absorb set energy. As shown by the standard kitchen microwave oven, this is a quite possible feat for a range of materials, and is quite fast comparatively to other heating methods such as convection oven. Application of such benefits for high temperature heating process such as powder metallurgy, drying and surface treatments.
In comparison to conventional heating methods, microwave processing has an inherit benefit of increased efficiency. By transferring energy via electromagnetic waves, heat transfer is not limited to only particles on the surface of a material, improving the rate of energy transfer in comparison to conventional heating. As energy is transferred using electromagnetic waves ability to penetrate surface layers, a new temperature profile exist for microwave processing, As heating is no longer dependent upon surface area, and is now dependent upon volume. In contrast to conventional heating, microwave processing has an inverse heating scheme. As electromagnetic penetrate the material, heating is modeled relative to the volume of material absorbing energy.
Dielectric Properties
The interaction of electromagnetic radiation with materials, causing heat transfer is understood to work via the mechanisms of conduction and polarization. The electromagnetic wave causes movement, or rotation of dipoles, adding energy to a material.
Dielectric properties of materials vary in accordance to there molecular structure, atomic bond strength and type. Research into dielectric properties is still lacking, ,and corresponding relationship's have failed to accurately predict the precise properties of material's dielectric permissibility. Although, the interaction between microwaves and materials is understood, this is thought to be relative to factors,such as structure and bond type having significant effects upon the permissibility . The dielectric properties, effect the absorbency and reflection coefficients of materials, causing a variety of problems, from the low penetration of electromagnetic waves to frequency transparency.
Absorption
Depending upon dielectric properties, the absorption coefficient of a material such as a ceramic may vary greatly. Varying with time, temperature, field power and volume, the efficiency of absorbency should be viewed as a changing value. Factor effecting absorbency are out lined below:
Frequency - A frequency which may be ideal for heating one ceramic, may be invisible to another ceramic, depending upon, dielectric or mechanical properties such as packing factor composition and temperature. Material testing tends to be around < 2.4 GHz, roughly the wavelength of a consumer microwave oven. High frequencies up to the range of 300 GH have shown increases in non-absorbent materials, and use for applications with the need for high rates of heating.
Temperature – During the heating of materials it is seen the rate of absorption increases with temperature. It is noted that this property leads to an acceleration in heat transfer, in high temperature heating, causing processing issues, such as runaway, where temperature changes faster then initially planed for a process.
Penetration Depth - Dependent upon frequency and dieletric properties, depth affects where the heat is transferred to. In a convection oven, heat is transferred by infared frequency radiation, and conduction occurs across the surface area.
Reflection
When a wave is incident, to a surface plane, i.e. passing from air to a solid. A portion of the incident wave will be reflected by the surface.
Using the principal of reflection efficiency of a microwave heating can be increased. Through the use of a reflective metal cavity, the bouncing of electromagnetic radiation through a material can greatly increase absorption. A given wave will effectively pass through a sample multiple times increasing the electromagnetic field strength. Constructive interference between electromagnetic waves, will produces greater field strengths, using a frequency near the resignation frequency of the resonator is there fore ideal. Use of resonating arrangement is applicable to both high and low loss materials.
Applications
Powder Metallurgy
The application of microwave processing to powder metallurgy looks to be extremely advantageous in processing. Through use of this technology, process time has been seen to decrease, through fast, uniform heating. A significant decrease in energy requirements during processing, testing has shown over ten fold decreases in specific cases. Final products have shown advantageous over old methods including smaller, finer grain size and increasingly uniform micro structures.
Application currently is applied only to ceramic and semi metals products, as metallic materials tend to be highly reflective and not absorb heat. Low penetration therefore negates the majority of the benefits. The reflectivity issue can be avoided through the use of alloys (semi metals). In the last decade the field of powdered metals has emerged, as powdered unsintered metals tend to absorb heat very well. Testing can produce highly sinter bodies in very short periods of time, with mechanical properties of modulus or rupture and hardness high then that of conventionally prepared samples.
Joining
Polymer Curing
Plasma Processing
Post Fabrication Processing
References
<layout name="Howtos" />