DE19738882C1 - Continuous oven with microwave heat sources - Google Patents

Abstract

Continuous oven in which the heat source is built up of a number of modules (12) containing microwave sources (30). Each module is covered by a cylindrical housing (14). The workpieces are transported on an endless belt (34) which runs above a perforated metal plate whose profile is arranged so it can act as a secondary radiator. The endless belt could be replaced by rollers set into the perforations of this plate.

Description

The invention relates to a continuous microwave oven with the Features specified in the preamble of claim 1.

A such a microwave oven is known from US 4,746,968. Such furnaces are used, for example, in ceramic Industry for drying ceramic objects in the Powder metallurgy for debinding and drying powders, in the pharmaceutical industry, in the raw materials industry, in the chemical industry or the like. The known microwave ovens are with a housing rectangular or square cross-section, wherein  the clear dimensions of the housing dimensioned in this way are that there are electromagnetic waves in the housing of the corresponding microwave radiation sources. The Manufacture of such rectangular or square housing is Relatively complex in terms of production technology, which affects the Manufacturing costs of such known continuous microwave ovens affects accordingly.

In the known from the above-mentioned US 4,747,968 However, the perforated sheets are not used for continuous microwave ovens as a secondary radiator, d. H. through it there is no interference the reflected microwave radiation of the radiation source causes, but the perforated plates serve as thermal there Radiators.

From DE-B: E. Pehl "Microwave Technology", Vol. 1, 1988, Dr. A. Hüthig-Verlag Heidelberg, pages 148-151, are perforated sheets in resonators, which are e.g. B. around microwave boiler rooms acts, known. These perforated plates are used to couple in Microwave energy in the microwave boiler room.

DE-GM 18 18 464 discloses a continuous microwave oven with a high frequency closed on all sides, elongated work space and a conveyor belt for that too treating objects. In this known microwave Continuous furnace pass through the objects in the course of the movement of the Conveyor belt successively different fields different frequency. In the case of a drying process the working space is in the direction of movement of the objects Microwave energy increasing frequency and in the case of a Warming process will work in Direction of travel of the objects with microwave energy falling frequency. The microwave energy of the  Radiation source is there, for example, via coupling slots in the Furnace chamber fed, d. H. the perforated plate also serves here only the coupling of the microwave energy into the Working area of the microwave continuous oven.

EP 0 016 699 A1 discloses a continuous microwave oven which has antennas in its oven space. These antennas are used to scatter the microwave field. The antennas therefore influence the microwave field distribution; Perforated sheets are not provided there. This known continuous microwave oven is provided with a radiation absorber module at each of its two opposite end sections. Continuous microwave ovens, which are each provided with a radiation absorber module at their two opposite end sections, are also from DE-Z: iew 49, 1991, Vol. 3, pages 149-155, "Microwave Heating - Applications in Industry" known by G. Orth and J. Walter. Figure 2 and the associated description disclose radiation absorber modules which have ferrites which are adjacent to one another in order to prevent microwave radiation which is hazardous to personnel from escaping from the continuous microwave oven.

A continuous microwave oven is also known from DE 196 43 989 A1 known. This known continuous microwave oven has one circular casing shell. A continuous microwave oven with a circular housing jacket is also from EP 0 136 453 A1 known.

The invention has for its object to provide a microwave Continuous furnace to create that on mechanical, electrical and Microwave technology comparatively simple type Enables field optimization.  

This task is carried out in a furnace of the type mentioned according to the invention by the in the characterizing part of Features specified claim 1 solved.

Each housing jacket is equipped with at least one microwave Provide radiation source, the respective microwave Radiation source attached to the corresponding housing jacket is the radiation of the corresponding microwave Coupling the radiation source into the associated oven module. Of the respective microwave radiation source is at least one Associated with transformer. The loss or waste heat of the respective microwave radiation source and the / each associated Transformer is preferably in the continuous furnace initiated. This results in an increase in efficiency. It is useful for the same purpose to connect each oven module to the Outside of its circular casing with a To provide thermal insulation.

The sheet metal base of the respective oven module can be made from one suitable metal sheet exist. This can be a Trade aluminum sheet or a stainless steel sheet or the like.

If the continuous microwave oven according to the invention is designed with a conveyor belt, then this lies closely and directly against the sheet metal bottoms of the oven modules which are arranged one behind the other and possibly form a common plane. This results not only in a radiation effect of the microwave radiation emitted by the at least one microwave radiation source of each oven module, but also in a radiation effect from the secondary radiators or so-called slot-radiating holes in the individual sheet metal shelves one behind the other arranged oven modules. The holes can be designed as elongated slots, as cross-shaped or star-shaped slots, as square or round holes or the like. They can be evenly spaced from one another or provided in a grid. Transport rollers can be arranged in the elongated slots. The transport rollers can consist of Al ₂ O ₃ , quartz, Teflon or another microwave-transparent material.

To the individual sheet metal shelves and transport rolls of the oven modules arranged one behind the other simply and precisely in the To be able to arrange the respective housing shell, it is expedient if in the respective housing jacket bearing elements for the associated sheet metal base are provided. With these Bearing elements can be profile bars, which in Are fixed inside the corresponding housing shell. This Fixation can be achieved by welding, screwing, riveting, etc. respectively.

It is preferred if the holes in the respective sheet metal base have a constant distance from each other. You can the holes preferably both in the feed direction of the Conveyor belt as well as perpendicular to each other constant be spaced. It is advantageous if the said distance half the wavelength of the microwave radiation corresponding microwave radiation source corresponds. By a such dimensioning results in an optimization of Secondary radiation and thus microwave radiation all in all. It serves the same purpose if the holes in the Sheet metal base have dimensions that are half the wavelength the microwave radiation of the respective microwave Correspond to radiation source. The same can be said  Distance also 1/4 or 3/4 of the wavelength or the wavelength or a multiple thereof.

The holes in the respective sheet metal base can, for example, be cruciform, be star-shaped or the like. With one Training of the latter type has proven to be useful proved if the holes to the feed direction of the Conveyor belt inclined are provided. Of the Inclination angle can be z. B. 45 °. Of course, other angles of inclination are also realizable.

According to the respective application or requirement profile the holes in the respective sheet metal base can also be round, oval or be square, preferably square. Of course it is also possible to remove the holes in the to design the respective sheet metal shelf as desired, as already has been mentioned. Are the holes as elongated slots trained, then can transport rollers in the slots be provided. Likewise, it is possible to use the sheet metal shelves to do without at all and only to provide transport roles, as has already been mentioned.

The individual oven modules forming heating zones are simple and time-saving arrangement in a row if each housing jacket on its two opposite End faces has an annular flange. Any ring flange can here be formed with mounting holes through which Screw elements can be pushed through. The ring flanges can be designed such that between adjacent Oven modules a gas seal and a microwave Radiation seal results.  

Said ring flanges can with support members be trained. The support organs and those mentioned at the beginning Bearing elements for the sheet metal shelves are next to each other adapted in such a way that an accurate Positioning the casing and thus the heating zones forming furnace modules, while the sheet metal shelves of the oven modules arranged in a row in lie on a common horizontal plane. Of the Continuous furnace according to the invention can also be installed at an angle Have chamber.

It is with the continuous microwave oven according to the invention preferred if the conveyor belt as a microwave permeable Endless belt is formed, which is deflected around pulleys. The pulleys can be moved outside the microwave Continuous furnace provided and with a drive device be connected. In the toxic area or in the nuclear area the deflection rollers can also be provided inside the furnace, to form a self-contained system.

To that through the microwave continuous oven according to the invention transported with the help of the conveyor belt Warming Well suited with microwave radiation too the microwave radiation sources of the in a row of oven modules arranged one behind the other in Offset circumferentially, preferably offset equidistantly, be provided. The microwave radiation sources can the oven modules each have the same power or have different performances. The achievements of individual microwave radiation sources can for example vary between 600 W and 3000 W. Different Services are particularly useful if the Continuous microwave oven according to the invention in the feed direction  of the conveyor belt in adaptation to the respective quantity Throughput a certain temperature or energy profile should own. For this purpose, an aperture-shaped Separation of the zones. This can be from unperforated or perforated Sheets are formed. Due to the modular structure of the Continuous microwave oven gives the advantage of a easy performance adjustment to any desired requirement.

It is preferred if in the microwave oven according to the invention Continuous furnace in the feed direction of the conveyor belt before first and after the last oven module at least one Radiation absorber module is provided. The end Steel absorber modules are preferably similar here designed like the oven modules, d. H. they each have one Furnace modules in the form of a circular casing shell as well as ring flanges on the front, without with associated To be provided with microwave radiation sources.

Connects to the respective radiation absorber module at the end expediently an absorber tunnel. By a Such formation of the microwave oven according to the invention Continuous furnace ensures that the exit of Microwave radiation from the continuous microwave oven does not exceed specified limit values.

The furnace modules and the end radiation absorber modules can be arranged on a furnace frame. If there is Such a furnace frame are the conveyor belt deflection rollers conveniently stored on this furnace frame.

An embodiment of the microwave Continuous furnace is below with reference to the drawing explained. Show it:  

Fig. 1 is a side view of an embodiment of the continuous microwave furnace

FIG. 2 shows a front view of an oven module of the microwave continuous oven according to FIG. 1, and

Fig. 3 is a plan view according to a bottom plate of an oven module of the continuous microwave furnace to FIG. 1.

Fig. 1 shows a schematic side view of an embodiment of the continuous microwave furnace 10, the furnace modules 12 which are arranged in a row behind each other. As can be seen from FIG. 2, each furnace module has a circular housing jacket 14 . Each housing jacket 14 is provided with thermal insulation (not shown) and with an annular flange 18 on its two opposite end faces 16 . The ring flanges 18 of adjacent oven modules 12 result in a gas and a microwave radiation seal. Each ring flange is formed with a support member 20 . In addition, each ring flange 18 is formed with fastening holes 22 which are provided equidistantly along a concentric circle, as can be seen from FIG. 2. Screws are inserted and screwed through the fastening holes 22 , for example, in order to connect the adjacent oven modules 12 to one another in a gas-tight and microwave-tight manner.

Inside the respective housing jacket 14 bearing members 24 are attached, the (not shown) for supporting a sheet metal bottom 26 and / or for the storage of transport rollers made of quartz, Al ₂ O _3, Teflon o. The like. Act. An embodiment of a sheet metal base 26 is shown in a view from above in FIG. 3. The respective sheet metal base 26 is formed with holes 28 , each of which has a constant grid spacing R in two mutually perpendicular spatial directions. It is preferred if the grid spacing R corresponds to half the wavelength of the microwave radiation of the corresponding microwave radiation source 30 (see FIG. 1). Said distance can also be n / 4 of the wavelength, where n is an integer, ie n = 1, 3, 4 ... The microwave radiation sources 30 are preferably formed by magnetrons known per se, which are interconnected with transformers. Fig. 1 illustrates that the microwave radiation sources 30 one behind the other in a row arranged furnace modules are provided offset by 90 ° in the circumferential direction of the continuous microwave furnace 10 12. Such an arrangement of the microwave radiation sources 30 results in a corresponding quasi helical microwave radiation in the interior of the continuous microwave oven 10 . Each oven module 12 can also be provided with more than one microwave radiation source 30 .

FIG. 3 illustrates an embodiment of a sheet metal base 26 with cross-shaped holes 28. From FIG. 3 it can also be seen that the cruciform holes 28 to the direction of advance of a conveyor belt 34 indicated in FIG. 1 and in FIG. 3 by the arrow 32 , which - as can be seen from FIG. 1 - by the microwave Continuous furnace 10 extends through, are provided inclined at an angle of 45 °. The intersecting slots of the holes 28 have dimensions a which, like the grid spacings R, preferably correspond to half or an integer multiple of the fourth part of the wavelength of the microwave radiation of the respective microwave radiation source 30 . Through such a dimensioning, the holes 28 form secondary or slot radiators.

In the direction of advance of the conveyor belt 34 , which is designed as an endless belt, at least one radiation absorber module 36 (see FIG. 1) is provided in front of the first oven module 12 and after the last oven module 12 . The radiation absorber modules 36 provided at the ends are designed in a similar way to the furnace modules 12 with a circular housing shell 38 and with ring flanges 40, as well as with bearing elements and with support members, as are designated by the reference number 20 in FIG. 2. Each of the two end-side radiation absorber modules 36 is also formed with an absorber tunnel 42 . Such training reduces stray microwave radiation below the prescribed limit values.

The furnace modules 12 and the two end-side radiation absorber modules 36 are arranged on a furnace frame 44 . Deflecting rollers 46 and tensioning rollers 48 are mounted on the furnace frame 44 at a distance from one another in order to suitably tension the endless conveyor belt 34 . One of the deflection rollers 46 is operatively connected to a drive device 50 . This drive device 50 is, for example, an electric motor that is combined with a transmission.

Claims (17)

1. Continuous microwave oven in which oven modules ( 12 ) forming heating zones are arranged in a row one behind the other,

• 1. wherein each oven module ( 12 ) has a housing with a housing jacket ( 14 ),
• 2. at least one microwave radiation source ( 30 ) is provided on the respective housing jacket ( 14 ),
• 3. a sheet metal base ( 26 ) is arranged in the respective housing jacket ( 14 ) and is formed with holes ( 28 ),
• 4. and wherein a conveyor belt ( 34 ) extends through the microwave continuous oven ( 10 ),
  characterized by
• 5. that the conveyor belt ( 34 ) rests on the sheet metal floors ( 26 ) of the oven modules ( 12 ) forming a common plane
• 6. or that instead of the conveyor belt ( 34 ) in the holes ( 28 ) transport rollers are provided which form a common plane,
• 7. that the holes ( 28 ) are designed so that they form secondary radiators and
• 8. that the housing jacket ( 14 ) is circular.

2. Continuous microwave oven according to claim 1, characterized in that bearing elements ( 24 ) for the associated sheet metal base ( 26 ) and / or for the transport rollers are provided in the respective housing jacket ( 14 ). 3. Continuous microwave oven according to claim 1, characterized in that the holes ( 28 ) in the respective sheet metal base ( 26 ) and the transport rollers are at a constant distance (R) from one another. 4. Continuous microwave oven according to claim 3, characterized in that the distance (R) corresponds to half or an integer multiple of the fourth part of the wavelength of the microwave radiation of the corresponding microwave radiation source ( 30 ). 5. Continuous microwave oven according to one of claims 1 to 4, characterized in that the holes ( 28 ) in the sheet metal base ( 26 ) and the transport rollers have dimensions (a) which are half or an integral multiple of the fourth part of the wavelength correspond to the microwave radiation of the respective microwave radiation source ( 30 ). 6. Continuous microwave oven according to one of claims 1 to 5, characterized in that the holes ( 28 ) in the respective sheet metal base ( 26 ) are cruciform or star-shaped. 7. Continuous microwave oven according to claim 6, characterized in that the holes ( 28 ) to the feed direction ( 32 ) of the conveyor belt ( 34 ) are provided inclined. 8. Continuous microwave oven according to one of claims 1 to 5, characterized in that the holes ( 28 ) in the respective sheet metal base ( 26 ) are angular, preferably square. 9. Continuous microwave oven according to one of claims 1 to 8, characterized in that each housing jacket ( 14 ) on its two opposite end faces ( 16 ) has an annular flange ( 18 ). 10. Continuous microwave oven according to claim 9, characterized in that the ring flanges ( 18 ) are formed with support members ( 20 ). 11. Continuous microwave oven according to one of claims 1 to 10, characterized in that the conveyor belt ( 34 ) is designed as a microwave-permeable endless belt which is deflected around deflection rollers ( 46 ), a deflection roller ( 46 ) being connected to a drive device ( 50 ) is. 12. Continuous microwave oven according to one of claims 1 to 11, characterized in that the microwave radiation sources ( 30 ) of the oven modules ( 12 ) arranged in a row one behind the other are offset in the circumferential direction, preferably offset by the same angle. 13. Continuous microwave oven according to one of claims 1 to 12, characterized in that the microwave radiation sources ( 30 ) of the oven modules ( 12 ) have the same power or different powers. 14. Continuous microwave oven according to one of claims 1 to 13, characterized in that in the feed direction ( 32 ) of the conveyor belt ( 34 ) or the transport rollers before the first and after the last oven module ( 12 ) in each case at least one radiation absorber module ( 36 ) is provided. 15. Continuous microwave oven according to claim 14, characterized in that an absorber tunnel ( 42 ) connects to the respective end-side radiation absorber module ( 36 ). 16. Continuous microwave oven according to one of claims 1 to 13 or 14, 15, characterized in that the oven modules ( 12 ) and the radiation absorber modules ( 36 ) are arranged on an oven frame ( 44 ). 17. Continuous microwave oven according to claim 11 or 16, characterized in that the conveyor belt deflection rollers ( 46 ) are mounted on the oven frame ( 44 ).