CA1044337A - Microwave power applicator - Google Patents
Microwave power applicatorInfo
- Publication number
- CA1044337A CA1044337A CA234,993A CA234993A CA1044337A CA 1044337 A CA1044337 A CA 1044337A CA 234993 A CA234993 A CA 234993A CA 1044337 A CA1044337 A CA 1044337A
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- Canada
- Prior art keywords
- tube
- sections
- microwaves
- microwave power
- central tube
- Prior art date
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- Constitution Of High-Frequency Heating (AREA)
Abstract
MICROWAVE POWER APPLICATOR
ABSTRACT OF THE DISCLOSURE
A microwave power applicator comprises a central tube through which the work piece is adapted to pass and two, hollow waveguide sections located on opposite sides thereof and communicating with the central tube to introduce micro-waves into it. A microwave power source or sources is or are connected to the waveguide sections. The frequency of the microwaves, the width of the central tube measured between the waveguide sections and the angles of inclination of the latter with respect to the central tube are selected so as to create interleaved reflection standing wave patterns so as to uniformly distribute hot spots across the central tube.
ABSTRACT OF THE DISCLOSURE
A microwave power applicator comprises a central tube through which the work piece is adapted to pass and two, hollow waveguide sections located on opposite sides thereof and communicating with the central tube to introduce micro-waves into it. A microwave power source or sources is or are connected to the waveguide sections. The frequency of the microwaves, the width of the central tube measured between the waveguide sections and the angles of inclination of the latter with respect to the central tube are selected so as to create interleaved reflection standing wave patterns so as to uniformly distribute hot spots across the central tube.
Description
~ `~ sackground o~ the Invention .
This invention relates to microwave power applicators, i.e., to devices for applying microwave power to workpieces. ;
More particularly, this invention relates tQ microwave power applicators designed so as to substantially uniformly dis-tribute hot spots which occur due to reflection standing wave patterns.
From a commercial point of view microwave energy usually is applied in one of three ways, namely resonant cavity ovens, waveguide applicators and horn type antenna applicators. `
In resonant cavity ovens energy in the form of micro-wave radiation is fed into a totally enclosed metal box having dimensions suitable for supporting standing waves. The material to be heated is placed in the applicator and necessarily has -~
smaller dimensions than those of the box. This type of appli-cator suffers from the disadvantages that heating lS not even, pressure cannot be applied conveniently to the workpiece, and the workpiece cannot be added continuously to or removed 20 continuously from the oven while it is operating. -In a waveguide applicator a slot is cut in the side of the waveguide in such a way that the workpiece may be introduced into the wa~eguide. Usually slots are provided on either side of the waveguide so that the workpiece may be passed through the waveguide continuously. This type of device is useful for heating thin webs of preformed material but cannot be used conveniently to apply pressure to the workpiece. In addition there is a limit to the size of the workpiece that can be passed through the slots, and devices of this type generally are not useful for heating thick work-pieces. . .
This invention relates to microwave power applicators, i.e., to devices for applying microwave power to workpieces. ;
More particularly, this invention relates tQ microwave power applicators designed so as to substantially uniformly dis-tribute hot spots which occur due to reflection standing wave patterns.
From a commercial point of view microwave energy usually is applied in one of three ways, namely resonant cavity ovens, waveguide applicators and horn type antenna applicators. `
In resonant cavity ovens energy in the form of micro-wave radiation is fed into a totally enclosed metal box having dimensions suitable for supporting standing waves. The material to be heated is placed in the applicator and necessarily has -~
smaller dimensions than those of the box. This type of appli-cator suffers from the disadvantages that heating lS not even, pressure cannot be applied conveniently to the workpiece, and the workpiece cannot be added continuously to or removed 20 continuously from the oven while it is operating. -In a waveguide applicator a slot is cut in the side of the waveguide in such a way that the workpiece may be introduced into the wa~eguide. Usually slots are provided on either side of the waveguide so that the workpiece may be passed through the waveguide continuously. This type of device is useful for heating thin webs of preformed material but cannot be used conveniently to apply pressure to the workpiece. In addition there is a limit to the size of the workpiece that can be passed through the slots, and devices of this type generally are not useful for heating thick work-pieces. . .
-2-
3'~ 37 In horn type antenna applicators a horn type antenna is used to convert the microwave energy from a transverse electric or magnetic mode to a free space or transverse electromagnetic mode. With this type of applicator it is difficult to control or contain the energy, and it is not possible to heat thick wor~pieces evenly or to apply pressure to the workpiece during heating.
In Canadian Patent 836,140 issued March 3, 1970 to Her Majesty in right of Canada as represented by the National Research Council of Canada there is disclosed a microwave power applicator having a basic configuration which resembles an embodiment of the instant invention. However, in the microwave power applicator disclosed in this patent no attempt is made to substantially uniformly distribute across the central tube which carries the workpiece hot spots which will occur as a result of reflection standing wave patterns within the central tube. !
Summary of the Inve~ntion In accordance with this invention there is provided apparatus for applying microwave power to a workpiece compris-ing a first hollow tube having an inlet end and an outlet end, the first tube being adapted to receive through its inlet end a workpiece to which microwave power is to be applied, the workpiece passing through the first tube where microwave power is applied thereto and exiting through the out-let end of the first tube; first and second hollow waveguide sections located on opposite sides of the first tube and comm-unicating with the first tube to introduce microwaves into it; and means for supplying microwaves to the first and sec~nd sections to be propagated through the first and second sections for introduction into the first tube; the .
33t7 frequency of the microwaves, the width of the first tube mea-sured between the first and second sections and the angles of inclination of the first and second sections with respect to the first tube being chosen such that the peak amplitudes of reflection standing waves created by introduction of microwaves - -into the first tube via the first and second sections respect-ively are interleaved, thereby substantially uniformly distri-buting hot spots created by the standing waves across the width of the first tube. ~-BRIEF DESCRIPTION OF THE DRAWINGS
This invention will become more apparent from the following detailed description taken in conjunction with the - ;
appended drawings, in which:
FIGURE 1 is a perspective view of a microwave power applicator embodying the instant invention, -FIGURE 2 illustrates another and more preferred embodi- -ment of the invention, and FIGURE 3 illustrates schematically the interleaving of "hot spots" in a microwave power applicator embodying the instant invention.
DETAILED DESCRIPTION OF THE INVENTION INCLUDING
THE PREFERRED EMBODIMENT ' -:.. . .
Referring to Figure 1, there is shown a source 10 of microwave energy. Source 10 may be any conventional microwave energy source and, for industrial microwave applications, nor- ~ -mally will operate at 915 MHz or 2450 MHz in accordance with ~-D.O.T. and F.C.C. regulations. It may be, for example, an EIMAC ttrade mark) Power Pack PPL-25. There is also shown what could be referred to as an applicator 11, the latter consisting of a hollow central tube 12 and two, hollow waveguide sections 13 and 14 located on opposite sides of central tube 12.
Central tube 12 has an inlet end 15 and an outlet end 16
In Canadian Patent 836,140 issued March 3, 1970 to Her Majesty in right of Canada as represented by the National Research Council of Canada there is disclosed a microwave power applicator having a basic configuration which resembles an embodiment of the instant invention. However, in the microwave power applicator disclosed in this patent no attempt is made to substantially uniformly distribute across the central tube which carries the workpiece hot spots which will occur as a result of reflection standing wave patterns within the central tube. !
Summary of the Inve~ntion In accordance with this invention there is provided apparatus for applying microwave power to a workpiece compris-ing a first hollow tube having an inlet end and an outlet end, the first tube being adapted to receive through its inlet end a workpiece to which microwave power is to be applied, the workpiece passing through the first tube where microwave power is applied thereto and exiting through the out-let end of the first tube; first and second hollow waveguide sections located on opposite sides of the first tube and comm-unicating with the first tube to introduce microwaves into it; and means for supplying microwaves to the first and sec~nd sections to be propagated through the first and second sections for introduction into the first tube; the .
33t7 frequency of the microwaves, the width of the first tube mea-sured between the first and second sections and the angles of inclination of the first and second sections with respect to the first tube being chosen such that the peak amplitudes of reflection standing waves created by introduction of microwaves - -into the first tube via the first and second sections respect-ively are interleaved, thereby substantially uniformly distri-buting hot spots created by the standing waves across the width of the first tube. ~-BRIEF DESCRIPTION OF THE DRAWINGS
This invention will become more apparent from the following detailed description taken in conjunction with the - ;
appended drawings, in which:
FIGURE 1 is a perspective view of a microwave power applicator embodying the instant invention, -FIGURE 2 illustrates another and more preferred embodi- -ment of the invention, and FIGURE 3 illustrates schematically the interleaving of "hot spots" in a microwave power applicator embodying the instant invention.
DETAILED DESCRIPTION OF THE INVENTION INCLUDING
THE PREFERRED EMBODIMENT ' -:.. . .
Referring to Figure 1, there is shown a source 10 of microwave energy. Source 10 may be any conventional microwave energy source and, for industrial microwave applications, nor- ~ -mally will operate at 915 MHz or 2450 MHz in accordance with ~-D.O.T. and F.C.C. regulations. It may be, for example, an EIMAC ttrade mark) Power Pack PPL-25. There is also shown what could be referred to as an applicator 11, the latter consisting of a hollow central tube 12 and two, hollow waveguide sections 13 and 14 located on opposite sides of central tube 12.
Central tube 12 has an inlet end 15 and an outlet end 16
- 4 -''':
.
1~4~;~37 and is adapted to receive through its inlet end a workpiece to ;
which microwave power is to be applied, the workpiece passing through central tube 12 where microwave power is applied there-to and exiting through outlet end 16. Central tube 12 conven-iently may be a waveguide section itself but, in any event, is constructed so as to receive m~crowavesfrom waveguide sections 13 and 14 which are capable of propagating into the workpiece (not shown) being passed continuously through central tube 12.
In the embodiment of the invention shown in Figure 1 central tube 12 and waveguide sections 13 and 14 all are rectangular, each having two longer sides and two shorter sides. The longer sides of the central tube and the two waveguide sections lie in the same two planes, and waveguide sections 13 and 14 are affixed to the shorter sides of central tube 12.
It would be possible, however, for central tube 12 to be rotated 90 so that sections 13 and 14 would be affixed to its longer sides. In a preferred embodiment of the invention, and as shown in the Figures, waveguide sections 13 and 14 are -each inclined at an acute angle to the longitudinal axis of central tube 12 and are located directly opposite each other.
In a less preferred embodiment waveguide sections 13 and 14 each could be located perpendicular to the longitudinal axis -~
of central tube 12. In another embodiment of the invention waveguide sections 13 and 14, rather than being located imme-diately opposite each other, could be located in staggered relationship with respect to each other. Moreover, if desired, more than one waveguide section could be affixed to each shorter side of central tube 12.
Waveguide sections 13 and 14 each are connected to microwave power source 10, this type of connection being conventional and being omitted for the sake of clarity, and microwaves may be supplied alternately or continuously from source 10 to waveguide
.
1~4~;~37 and is adapted to receive through its inlet end a workpiece to ;
which microwave power is to be applied, the workpiece passing through central tube 12 where microwave power is applied there-to and exiting through outlet end 16. Central tube 12 conven-iently may be a waveguide section itself but, in any event, is constructed so as to receive m~crowavesfrom waveguide sections 13 and 14 which are capable of propagating into the workpiece (not shown) being passed continuously through central tube 12.
In the embodiment of the invention shown in Figure 1 central tube 12 and waveguide sections 13 and 14 all are rectangular, each having two longer sides and two shorter sides. The longer sides of the central tube and the two waveguide sections lie in the same two planes, and waveguide sections 13 and 14 are affixed to the shorter sides of central tube 12.
It would be possible, however, for central tube 12 to be rotated 90 so that sections 13 and 14 would be affixed to its longer sides. In a preferred embodiment of the invention, and as shown in the Figures, waveguide sections 13 and 14 are -each inclined at an acute angle to the longitudinal axis of central tube 12 and are located directly opposite each other.
In a less preferred embodiment waveguide sections 13 and 14 each could be located perpendicular to the longitudinal axis -~
of central tube 12. In another embodiment of the invention waveguide sections 13 and 14, rather than being located imme-diately opposite each other, could be located in staggered relationship with respect to each other. Moreover, if desired, more than one waveguide section could be affixed to each shorter side of central tube 12.
Waveguide sections 13 and 14 each are connected to microwave power source 10, this type of connection being conventional and being omitted for the sake of clarity, and microwaves may be supplied alternately or continuously from source 10 to waveguide
-5-. - . . ,, :
~ 4~.37 sections 13 and 14. The embodiment of the invention illustrated in Figure 2 differs from the embodiment of Figure 1 in that two microwave sources lOa and lOb are provided, the latter being connected to waveguide section 14 and the former to waveguide section 13. In this embodiment of the invention, which is the preferred embodiment, the frequencies of the microwaves produced by sources lOa and lOb are different. The ramifications of this will be outlined hereafter.
- .. ..
As noted hereinbefore, waveguide sections 13 and 14 preferably eAch are inclined at an acute angle to the longitudinal axis of central tube 12 but may be perpendicular A thereto. The former constitutes the preferred embodiment of the invention because the dimension A, as seen in Figure X, is considerably greater than the dimension B, so the energy `
density over the area constituted by A times the depth of central tube 12 is considerably less than the energy density -over thearea constituted by B times the depth of central tube 12, so that any tendency for arcing to take place would be reduced with waveguide sections 13 and 14 each inclined at -an acute angle to the longitudinal axis of central tube 12.
Moreover, with waveguide sections 13 and 14 each inclined at an acute angle to the longitudinal axis of central tube 12, there is a reduction in the tendency for microwave energy passing through ~ -the workpiece to be propagated through the waveguide on the opposite side of central tube 12, as would be the case if waveguide sections 13 and 14 were directly opposite each other and perpendicular to the longitudinal axis of central , tube 12.
In practising this invention it is necessary for the microwaves to be propagated in waveguides 13 and 14 in ,, ~
l.t~ 3~7 the TE mode, where n is any number. In experiments which have been conducted to demonstrate the practicability of the invention, the TElo mode has been successfully utilized. It is to be understood with reference to the aforementioned nomenclature that in the TE mode the electric field vector no is parallel to the shorter sides of waveguide sections 13 and 14 and hence perpendicular to the longer sides thereof. The desired objective is to obtain a field configuration within central tube 12 that is as uniform as possible. The micro-wave energy being supplied to the workpiece in central tube 12from waveguide sections 13 and 14 is attenuated as it passes through the workpiece,and the magnitude of the E vector decreases logarithmically as the microwave energy propagates through the workpiece. There are, of course, two logarithmic attenuation curves, since microwave energy is applied to both sides of central tube 12. As far as the total-heating effect is concerned, these two curves add together to produce sub-stantially uniform heating across the workpiece.
Central tube 12 preferably is made sufficiently long so that at its outlet end 16 there will be substantially no energy to be reflected. This contributes to minimizing the occurrence of standing waves within central tube 12 caused by microwave propagation therein. Wotwithstanding central tube 12 being designed so as to minimize reflections and thus the occurrence of standing waves, reflection standing wave patterns will necessarily be present within central tube 12,and there will be two such reflection standing wave patterns, one associated with each waveguide section 13 and 14. The location of the points of peak amplitude of the reflection standing wave pattern associated with waveguide section 14 are shown by the points designated 17 in Flgure X, while the locations of the peak amplitudes of the reflection standing wave pattern associated with waveguide section 13 are shown by the points designated 18 in Figure X. The location o~ the points 17 and 33~,~
18 which are closest to the side walls of central tube 12 opposite to waveguide sections 14 and 13 respectively will occur one quarter of a wavelength from the respective side walls of -~
central tube 12 measured along the lines containing the points, the remaining points 17 and 18 occurring at half wavelength spacings. At the points where the reflection standing wave : -patterns have peak amplitude, hot spots will be created in the . :
workpiece being processed. In accordance with this invention ~-it has been discovered that by choosing the frequency of the 10 microwaves, the width of central tube 12 as measured between .
waveguide sections 13 and 14 and the angles of inclination of waveguide sections 13 and 14 with respect to the longitudinal axis of central tube 12, the peak amplitudes of the reflection standing wave patterns created by introduction of microwaves ~
into central tube 12 via waveguide sections 13 and 14 can be - - :
interleaved, thereby substantially uniformly distributing the ~
hot spots created by the reflection standing wave patterns ~ .
across the width of central tube 12. The location of the hot spots may be determined by experimental observation of temperature variations across central tube 12. Theoretically, when the frequency of the microwaves, the dielectric constant -~
,,. ~ ., of the workpiece, and the geometry of the applicator are known, `~ :
the location of the points 17 and 18 which are closest to the-side walls of central tube 12 opposite to waveguide sections 14 and 13 will be known, as will the locations of the remain-ing points 17 and 18, and by varying either the angles of incli-nation of waveguide sections 13 and 14 with respect to the longitudinal axis of central tube 12 or the width of central tube 12, the locations of points 17 can be made to fall midway between two adjacent points 18 and vice versa when the points 17 and 18 are projected parallel to the longitudinal axis of central tube 12 onto a plane which is perpendicular to this .
longitudinal axis, as best shown in Figure 3. In practice, experimental observation may be required to locate the hot spots and their changing position as the parameters noted above are ~aried. Thus the hot spots created by the reflection standing wave patterns are distributed uniformly across central tube 12 and hence across the - 8a -.~ ....
workpiece. It should be understood that the nature of the workpiece itself has some effect on the location of the reflection standing wave patterns, and it may be necessary to take this into consideration to achieve the desired inter-leaving. If desired, waveguide sections 13 and 14 may be affixed to central tube 12 by means of flexible sections, so that the angles of inclination of waveguide sections 13 and 14 with respect to the longitudinal axis of central tube 12 may be varied. Likewise, central tube 12 may be provided -with an expansion joint to permit its width to be varied.
In using the apparatus shown in Figure 1, it is first adjusted to uniformly distribute the hot spots across the width of central tube 12. The workpiece is inserted into -inlet 15 and passes continuously through central tube 12 emerging via outlet 16. Microwave power is applied thereto from source 10 or sources lOa and lOb via waveguide sections 13 and 14. A wide variety of workpieces may be heated by passage through central tube 12. Preferably the cross-sectional area of the workpiece should be the same as the cross-sectional area of central tube 12 or the E field will be distorted. To this end, plywood sections have been pro-cessed in apparatus of the type described, the microwave energy being used to cure the resin used to laminate the veneers of the plywood, but many other applications are possible. For example, the apparatus could be used for curing rubber.
In the manufacture of plywood it is necessary to -apply pressure to the plywooa before the resin is cured. This can be achieved with apparatus embodying the instant invention by incorporating a press within central tube 1~. The press may take the form of two moving belts suitably backed up _g_ and defining a nip between the belts into which the plywood is inserted. In fact, the belts could be fabricated of metal and could constitute a part of central tube 12.
In the preferred embodiment of the invention two microwave power sources lOa and lOb are employed each operating at a different frequency. Whenever microwaves are applied to central tube 12 from both sides thereof, an interference standing wave pattern will be set up. If two microwave sources are employed operating at even slightly different frequencies, the interference standing wave pattern will not be static but will move ~Ye ~~ ~e_~racross central tube 12. The hot spots created by this interference stand-ing wave pattern thus will not be static and will not create any problem. In the case where microwave energy is applied alternately to waveguide sections 13 and 14 from a single source 10, there also will be no interference standing wave pattern produced. However, in the embodiment of the invention where microwaves of the same frequency, e.g. from a common source, are applied simultaneously to waveguide sections 13 and 14, a static interference standing wave pattern will result that cannot be compensated for. Consequently this is a less preferred embodiment of the invention.
While preferred and other embodiments of the invention have been described herein, those skilled in the art will appreciate that changes and modifications may be made therein without departing from the spirit and scope of this invention as defined in the appended claims.
~" ~...
. ~: .
,, , . . , .. . .. . ... ~ . . . . .
-. . -, .: - .- ~ : . . - ~
~ 4~.37 sections 13 and 14. The embodiment of the invention illustrated in Figure 2 differs from the embodiment of Figure 1 in that two microwave sources lOa and lOb are provided, the latter being connected to waveguide section 14 and the former to waveguide section 13. In this embodiment of the invention, which is the preferred embodiment, the frequencies of the microwaves produced by sources lOa and lOb are different. The ramifications of this will be outlined hereafter.
- .. ..
As noted hereinbefore, waveguide sections 13 and 14 preferably eAch are inclined at an acute angle to the longitudinal axis of central tube 12 but may be perpendicular A thereto. The former constitutes the preferred embodiment of the invention because the dimension A, as seen in Figure X, is considerably greater than the dimension B, so the energy `
density over the area constituted by A times the depth of central tube 12 is considerably less than the energy density -over thearea constituted by B times the depth of central tube 12, so that any tendency for arcing to take place would be reduced with waveguide sections 13 and 14 each inclined at -an acute angle to the longitudinal axis of central tube 12.
Moreover, with waveguide sections 13 and 14 each inclined at an acute angle to the longitudinal axis of central tube 12, there is a reduction in the tendency for microwave energy passing through ~ -the workpiece to be propagated through the waveguide on the opposite side of central tube 12, as would be the case if waveguide sections 13 and 14 were directly opposite each other and perpendicular to the longitudinal axis of central , tube 12.
In practising this invention it is necessary for the microwaves to be propagated in waveguides 13 and 14 in ,, ~
l.t~ 3~7 the TE mode, where n is any number. In experiments which have been conducted to demonstrate the practicability of the invention, the TElo mode has been successfully utilized. It is to be understood with reference to the aforementioned nomenclature that in the TE mode the electric field vector no is parallel to the shorter sides of waveguide sections 13 and 14 and hence perpendicular to the longer sides thereof. The desired objective is to obtain a field configuration within central tube 12 that is as uniform as possible. The micro-wave energy being supplied to the workpiece in central tube 12from waveguide sections 13 and 14 is attenuated as it passes through the workpiece,and the magnitude of the E vector decreases logarithmically as the microwave energy propagates through the workpiece. There are, of course, two logarithmic attenuation curves, since microwave energy is applied to both sides of central tube 12. As far as the total-heating effect is concerned, these two curves add together to produce sub-stantially uniform heating across the workpiece.
Central tube 12 preferably is made sufficiently long so that at its outlet end 16 there will be substantially no energy to be reflected. This contributes to minimizing the occurrence of standing waves within central tube 12 caused by microwave propagation therein. Wotwithstanding central tube 12 being designed so as to minimize reflections and thus the occurrence of standing waves, reflection standing wave patterns will necessarily be present within central tube 12,and there will be two such reflection standing wave patterns, one associated with each waveguide section 13 and 14. The location of the points of peak amplitude of the reflection standing wave pattern associated with waveguide section 14 are shown by the points designated 17 in Flgure X, while the locations of the peak amplitudes of the reflection standing wave pattern associated with waveguide section 13 are shown by the points designated 18 in Figure X. The location o~ the points 17 and 33~,~
18 which are closest to the side walls of central tube 12 opposite to waveguide sections 14 and 13 respectively will occur one quarter of a wavelength from the respective side walls of -~
central tube 12 measured along the lines containing the points, the remaining points 17 and 18 occurring at half wavelength spacings. At the points where the reflection standing wave : -patterns have peak amplitude, hot spots will be created in the . :
workpiece being processed. In accordance with this invention ~-it has been discovered that by choosing the frequency of the 10 microwaves, the width of central tube 12 as measured between .
waveguide sections 13 and 14 and the angles of inclination of waveguide sections 13 and 14 with respect to the longitudinal axis of central tube 12, the peak amplitudes of the reflection standing wave patterns created by introduction of microwaves ~
into central tube 12 via waveguide sections 13 and 14 can be - - :
interleaved, thereby substantially uniformly distributing the ~
hot spots created by the reflection standing wave patterns ~ .
across the width of central tube 12. The location of the hot spots may be determined by experimental observation of temperature variations across central tube 12. Theoretically, when the frequency of the microwaves, the dielectric constant -~
,,. ~ ., of the workpiece, and the geometry of the applicator are known, `~ :
the location of the points 17 and 18 which are closest to the-side walls of central tube 12 opposite to waveguide sections 14 and 13 will be known, as will the locations of the remain-ing points 17 and 18, and by varying either the angles of incli-nation of waveguide sections 13 and 14 with respect to the longitudinal axis of central tube 12 or the width of central tube 12, the locations of points 17 can be made to fall midway between two adjacent points 18 and vice versa when the points 17 and 18 are projected parallel to the longitudinal axis of central tube 12 onto a plane which is perpendicular to this .
longitudinal axis, as best shown in Figure 3. In practice, experimental observation may be required to locate the hot spots and their changing position as the parameters noted above are ~aried. Thus the hot spots created by the reflection standing wave patterns are distributed uniformly across central tube 12 and hence across the - 8a -.~ ....
workpiece. It should be understood that the nature of the workpiece itself has some effect on the location of the reflection standing wave patterns, and it may be necessary to take this into consideration to achieve the desired inter-leaving. If desired, waveguide sections 13 and 14 may be affixed to central tube 12 by means of flexible sections, so that the angles of inclination of waveguide sections 13 and 14 with respect to the longitudinal axis of central tube 12 may be varied. Likewise, central tube 12 may be provided -with an expansion joint to permit its width to be varied.
In using the apparatus shown in Figure 1, it is first adjusted to uniformly distribute the hot spots across the width of central tube 12. The workpiece is inserted into -inlet 15 and passes continuously through central tube 12 emerging via outlet 16. Microwave power is applied thereto from source 10 or sources lOa and lOb via waveguide sections 13 and 14. A wide variety of workpieces may be heated by passage through central tube 12. Preferably the cross-sectional area of the workpiece should be the same as the cross-sectional area of central tube 12 or the E field will be distorted. To this end, plywood sections have been pro-cessed in apparatus of the type described, the microwave energy being used to cure the resin used to laminate the veneers of the plywood, but many other applications are possible. For example, the apparatus could be used for curing rubber.
In the manufacture of plywood it is necessary to -apply pressure to the plywooa before the resin is cured. This can be achieved with apparatus embodying the instant invention by incorporating a press within central tube 1~. The press may take the form of two moving belts suitably backed up _g_ and defining a nip between the belts into which the plywood is inserted. In fact, the belts could be fabricated of metal and could constitute a part of central tube 12.
In the preferred embodiment of the invention two microwave power sources lOa and lOb are employed each operating at a different frequency. Whenever microwaves are applied to central tube 12 from both sides thereof, an interference standing wave pattern will be set up. If two microwave sources are employed operating at even slightly different frequencies, the interference standing wave pattern will not be static but will move ~Ye ~~ ~e_~racross central tube 12. The hot spots created by this interference stand-ing wave pattern thus will not be static and will not create any problem. In the case where microwave energy is applied alternately to waveguide sections 13 and 14 from a single source 10, there also will be no interference standing wave pattern produced. However, in the embodiment of the invention where microwaves of the same frequency, e.g. from a common source, are applied simultaneously to waveguide sections 13 and 14, a static interference standing wave pattern will result that cannot be compensated for. Consequently this is a less preferred embodiment of the invention.
While preferred and other embodiments of the invention have been described herein, those skilled in the art will appreciate that changes and modifications may be made therein without departing from the spirit and scope of this invention as defined in the appended claims.
~" ~...
. ~: .
,, , . . , .. . .. . ... ~ . . . . .
-. . -, .: - .- ~ : . . - ~
Claims (10)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. Apparatus for applying microwave power to a work-piece comprising a first hollow tube having an inlet end and an outlet end, said first tube being adapted to receive through said inlet end a workpiece to which microwave power is to be applied, said workpiece passing through said first tube where microwave power is applied thereto and exiting through said outlet end; first and second hollow waveguide sections located on opposite sides of said first tube and communicating with said first tube to introduce microwaves into said first tube; and means for supplying microwaves to said first and second sections to be propagated through said first and second sections for introduction into said first tube; the frequency of said microwaves, the width of said first tube measured between said first and second sections and the angles of inclination of said first and second sections with respect to said first tube being chosen such that the peak amplitudes of reflection standing waves created by introduction of microwaves into said first tube via said first and second sections respectively are interleaved, thereby substantially uniformly distributing hot spots created by said standing waves across the width of said first tube.
2. Apparatus according to claim 1 wherein said means for supplying microwaves is a single microwave power source communicating with both said first and second sections.
3. Apparatus according to claim 1 wherein said means for supplying microwaves comprises a first microwave power source communicating with said first section and a second microwave power source communicating with said second section, said power sources producing microwaves at different frequencies.
4. Apparatus according to claim 1 wherein said first and second sections are designed to propagate microwaves predominantly in the TEno mode where n is any integer.
5. Apparatus according to claim 4 wherein n is 1.
6. Apparatus according to claim 1 wherein said tube and said sections are rectangular each having two longer sides and two shorter sides, said longer sides of said tube and said sections lying in the same two planes and said first and second sections being affixed to said shorter sides of said first tube.
7. Apparatus according to claim 6 wherein said first and second sections are designed to propagate microwaves predominantly in the TEno mode where n is any integer.
8. Apparatus according to claim 7 wherein n is 1.
9. Apparatus according to claim 6 wherein said means for supplying microwaves comprises a first microwave power source communicating with said first section and a second microwave power source communicating with said second section, said power sources producing microwaves at different frequencies.
10. Apparatus according to claim 9 wherein said first and second sections are designed to propagate microwaves predominantly in the TEno mode where n is any integer.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA234,993A CA1044337A (en) | 1975-09-08 | 1975-09-08 | Microwave power applicator |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA234,993A CA1044337A (en) | 1975-09-08 | 1975-09-08 | Microwave power applicator |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1044337A true CA1044337A (en) | 1978-12-12 |
Family
ID=4103991
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA234,993A Expired CA1044337A (en) | 1975-09-08 | 1975-09-08 | Microwave power applicator |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA1044337A (en) |
-
1975
- 1975-09-08 CA CA234,993A patent/CA1044337A/en not_active Expired
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