NL1033105C2 - Microwave sterilization assembly for solid ground in greenhouse, has emission device equipped with microwave source, where microwave source is connected to free end of waveguide and to applicator head - Google Patents

Abstract

The assembly has an emission device (1) to emit microwaves into the ground, and a vehicle (2) to move the emission device. The emission device is equipped with a microwave source, where the microwave source is connected to a free end of a waveguide and to an applicator head (3). A waveguide tube (4) distributes microwaves emitted by the emission device, and a mouth of the waveguide tube faces the ground. An independent claim is also included for a method for using microwave sterilization of solid ground in a greenhouse.

Description

Compound for sterilizing soil

BACKGROUND OF THE INVENTION

The invention relates to an assembly 5 for sterilizing soil.

Such an assembly is known from U.S. Pat. No. 4,092,800. Described herein is a vehicle which carries four generators for generating electromagnetic waves with a frequency of 2450 ± 10 20 MHz. Each generator is connected via a respective rectangular waveguide, which contains a flexible part, to its own radiator cavity that directs waves towards and into the ground for the sterilization of vegetation or seeds therein.

Although the aforementioned known assembly in test arrangement functions properly, no commercial application of such an assembly has yet been realized. This is caused by the energy density of the electromagnetic waves, in particular the microwaves, causing stray fields outside the assembly for killing nematodes, fungicides, insect unwanted seeds, and weeds, which have such a strength that these are well above the legally permitted limits. In the

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2 particularly when the effective emitting surface of the emission device is of a size that is of interest for commercial use (at least a few tenths of a square 5 meter is envisaged), these stray fields have an unacceptable strength. The use of reflective and / or absorbing devices (as described, for example, in US patent application US 2002/0090268) could reduce the strength of the stray fields, however, these reflective and / or absorbing devices at commercially interesting energy densities would it must be substantial that a non-practical and non-economically usable assembly would be obtained.

It is therefore, inter alia, an object of the present invention to provide an assembly and emission device with which on the one hand a sufficient energy density can be generated so that the soil can be sterilized in a commercially applicable manner to a depth of at least about 50 cm, wherein on the other hand, the strength of the stray fields by practical means remains well within the set legal limits, whereby the assembly and the emission device are also economically usable.

It is a further object of the present invention to provide an assembly and an emission device which are capable of converting the soil surface and / or soil into a commercially applicable manner without protruding reflection and / or absorption devices. sterilization depth of at least about 50 cm, while on the other hand the strength of the stray fields remains well within the legal limits set. In this way it is therefore possible to sterilize asphalted, paved, tiled, gravel or gravel-covered or otherwise covered ground surfaces.

SUMMARY OF THE INVENTION

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To this end, the invention provides, from one aspect, an assembly for sterilizing solid ground with the aid of microwaves, comprising an emission device for emitting microwaves into the soil 5 and a vehicle for moving the emission device over the soil. , wherein the emission device is provided with a microwave source, the microwave source being connected via a waveguide to an applicator unit arranged at the free end of the waveguide, the applicator unit juxtaposing a number transversely to the normal direction of travel of the vehicle corrugated pipes, wherein a distributing corrugated pipe is included in the waveguide for distributing the microwaves emitted from the microwave source over the corrugated pipes, each corrugated pipe having a ground-facing mouth. By using a distributing corrugated pipe, only one microwave source is required for supplying microwaves to several corrugated pipes, or also called radiator cavities. This makes it possible to produce and use the assembly in an economical manner.

In an embodiment of an assembly according to the invention, the number of adjacent corrugated pipes is at least eight. In practice, it has been unexpectedly found that with such a number of waveguides the microwaves (simultaneously and synchronously) influence each other in such a way that the microwaves emitted from the mouth are transmitted substantially parallel, so that hardly any distance from the emission device turned out to be stray fields. The strength of any stray fields that are present remains well within the statutory limits. A sufficient energy density in the soil is also obtained by these microwave beams transmitted in parallel so that, among other things, nematodes, fungicides, insects, unwanted seeds and weeds are killed to a depth of approximately 50 cm. A sufficiently large effective surface is also obtained by such a number of waveguides for sterilizing the soil in a commercially interesting manner.

In an advantageous embodiment, each corrugated pipe is elongated and the longitudinal direction of a corrugated pipe is substantially in the normal driving direction of the vehicle.

In a further embodiment of an assembly according to the invention, the mouth of a corrugated pipe comprises two slots, wherein in particular the slots are situated at an equal but opposite angle to the normal driving direction of the vehicle.

In a still further embodiment of an assembly according to the invention, the distributing corrugated pipe is substantially transverse to the normal driving direction of the vehicle. Hereby it is advantageous if the distributing corrugated pipe is provided with adjacent coupling slots for coupling microwaves in the respective corrugated pipe. An equal coupling is obtained when the coupling slots are elongated and are situated transversely to the normal driving direction of the vehicle. A uniform distribution is hereby obtained when the coupling slots are staggered alternately.

In an embodiment of an assembly according to the invention, the emission device is provided with a means for generating an overpressure in the applicator unit, so that no dirt and the like can penetrate into the applicator unit from outside.

In yet a further embodiment of an assembly according to the invention, the emission device comprises two applicator units placed one behind the other in the normal driving direction of the vehicle. This increases the effective surface area of the assembly.

Particularly advantageous is an embodiment of an assembly according to the invention in which the microwave source 35 is suitable for generating microwaves with a frequency of approximately 915 MHz.

In order to prevent any undesired reflections, in an embodiment of an assembly according to the invention, in the normal driving direction of the vehicle, a front reflection device and / or a rear reflection device is provided, wherein the reflection device 5 is intended for reflecting microwaves. It has been found to be advantageous here if a reflection device comprises a U-shaped profile, the open end of the profile facing the ground. Extremely effective is an embodiment of an assembly according to the invention in which the reflection device comprises two adjacent U-shaped profiles, the open ends of the profiles facing the ground.

In order to prevent objects from being inserted under the emission device in an undesirable manner, a rear hinged drag plate, viewed in normal driving direction, is provided in an embodiment of an assembly according to the invention and provided with a means for pressing against the ground. of a towing part of the towing plate.

In order to prevent microwaves from being transmitted laterally from the assembly in the case of undesired lifting of the assembly, a relevant (e.g. side) reflection device is provided on each outside of the emission device. The reflecting device can comprise a number of juxtaposed, hanging reflecting means, in particular wires, metal wires or chains. In particular, the reflection device is made of stainless steel.

In a further embodiment of an assembly 30 according to the invention, an applicator unit is height-adjustable. It has been found advantageous here if the emission device is provided with a sensor for measuring the distance from the bottom of an applicator unit to the ground, and for switching the microwave sources on and off, respectively, in dependence on the measured distance.

In order to prevent contamination of the applicator unit 6, an embodiment of an assembly according to the invention is provided with a microwave-transparent plate, for example of ceramic, for closing off the mouths of the corrugated pipes directed towards the ground.

A further embodiment of an assembly according to the invention is provided with a sensor for measuring the intensity of microwave radiation outside the emission device, and for switching the microwave source on or off depending on the measured radiation, wherein in the in particular four sensors are each arranged at a corner of the applicator unit.

The invention also relates to an emission device for emitting microwaves in the ground intended for use in an assembly as described above, wherein the emission device measures the measures relevant to the emission device according to one of the preceding claims wherein the emission device is provided with mounting means for mounting the emission device on a vehicle, so that the emission device is movable over the ground.

The invention also relates to a method for using microwaves to sterilize solid soil in a greenhouse, which greenhouse has a rear wall and a path opposite the rear wall, in which method an assembly as described above is used, which method comprises steps of: a. moving the vehicle from the path to the rear wall so that the front applicator unit comes into contact with the rear wall or approaches a close distance to the rear wall, during which movement the microwave source is switched off, b. moving the vehicle from the rear wall back to the path, during which displacement the microwave source is switched on to sterilize the ground, c. when the vehicle has again reached the path, moving the vehicle 7 sideways to adjacent the part of the ground just treated with microwaves, d. repeating step a wherein the vehicle is moved over untreated soil to the rear wall, and repeating step b.

In an embodiment of a method according to the invention, the speed of movement of the vehicle with the microwave source switched on is selected in dependence on measurement results that are carried out by means of 10 dna multiscans of soil prior to microwave treatment and the measurement results of that soil after microwave treatment.

The aspects and measures described in this description and claims of the application and / or shown in the drawings of this application can, where possible, also be applied separately from each other. Those individual aspects, such as the assembly of emission device and vehicle and the emission device, and other aspects can be the subject of split-off patent applications directed thereto. This applies in particular to the measures and aspects that are described per se in the subclaims.

BRIEF DESCRIPTION OF THE DRAWINGS 25

The invention will be elucidated with reference to exemplary embodiments shown in the accompanying drawings. Shown is:

Figure 1 shows a schematic perspective view of an assembly with an emission device and a vehicle for emitting microwaves according to the present invention in the ground;

Figure 2 is a schematic top perspective view of an applicator unit of an emission device according to the present invention;

Figure 3 is a schematic bottom perspective view of the applicator unit shown in Figure 2; and

Figure 4 shows a bottom view of the applicator unit in which the coupling slots of the distributing corrugated pipe are indicated.

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DETAILED DESCRIPTION OF THE DRAWINGS

Figure 1 shows a schematic perspective view of an assembly for sterilizing solid soil according to the invention with the aid of 10 microwaves. The assembly comprises an emission device 1 for emitting microwaves into the ground. The assembly further comprises a vehicle 2 for moving the emission device 1 over the ground. In the embodiment shown in Figure 1, the emission device 1 is mounted on the vehicle 2 via per se known (not shown) mounting means. It will be clear that the emission device and the vehicle can be integrated into a self-driving device. In addition, the vehicle and the emission device can be controlled remotely, and optionally the assembly of emission device and vehicle can be an autonomous assembly, i.e. an assembly that operates without human control. In the exemplary embodiment shown, the vehicle is a caterpillar vehicle, although in other embodiments the vehicle can also be propelled by wheels or the like.

According to the invention, the emission device 1 is provided with a microwave source for generating microwaves (for example a microwave oven, a klystron or a similar device), and a waveguide for guiding microwaves to an applicator unit 3. Although other frequencies and thereby dimensions of the waveguide can be used within the scope of the invention, it has been found that a microwave source for generating microwaves with a frequency of approximately 915 MHz is extremely suitable for economically sterilizing contaminants present in the soil and killing or making ineffective unwanted organic elements.

In the exemplary embodiment shown in Fig. 5, the microwave source is a microwave 4, the emitted radiation of which is conducted through an insulator 5. Any radiation reflected back from the ground is sent by the insulator 5 to a so-called water load 6. This water load 6 prevents the reflected radiation 10 from ending up in the microwave tube 4 and causing damage. The water load 6 absorbs the reflected radiation through water.

After passing through the insulator 5, the radiation passes through a tuner 7. With this tuner 7, the radiation 15 can be adjusted such that a minimal reflection in the direction of the microwave 4 is achieved.

After the tuner 7, a quartz plate 8 is placed in the waveguide from the microwave 4 to the applicator unit 3. This quartz plate 8 inhibits any sparks 20 within the waveguide so that damage to the microwave tube 4 can be avoided.

The radiation is then passed through a so-called twister 9. This twister 9 ensures that the waveguide is twisted 90 ° about the longitudinal axis, so that the waveguide can be connected to the applicator unit 3.

The entire path from the microwave tube 4 to the applicator unit 3 requires a bend of 90 °. This is realized by means of two bends in the waveguide. One bend bends an x number of degrees over the wide side of the waveguide (E-Bend) 10. The other bend bends 90-x degrees over the narrow side of the waveguide (H-Bend) 11.

A dust filter 12 is also located inside the waveguide to keep the inside dust-free.

The applicator unit 3 is located at the free end of the above-described waveguide.

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The applicator unit 3 is attached thereto via a dividing, long waveguide 13, which is perpendicular to the waveguide. At the top of the distributing waveguide 13 there is a connection 14 (Figure 2) for the waveguide in the middle. In this embodiment, on the underside there are eight coupling slots 15 (Figure 4) in the longitudinal direction of the distributing corrugated pipe 13. The slots 15 are staggered at an equal distance from the center. The radiation is distributed over these coupling slots 10 and guided into the applicator unit 3.

The applicator unit 3 in this embodiment comprises eight (short) corrugated pipes 16 which are arranged perpendicular to the long, distributing corrugated pipe 13. Each short corrugated pipe 16 has a slot (not shown in the drawing 15) in the width direction at the top. These slots correspond to the coupling slots 15 in the long corrugated pipe 13. Because the coupling slots 15 in the long corrugated pipe 13 are staggered alternately, this is also the case with the eight short corrugated pipes 16.

Two slots 17 are provided on the underside of the short corrugated pipes 16. Both slots are rotated by an equal number of degrees from the center, viewed in the normal direction of travel A of the vehicle. Neighboring short corrugated pipes 16 have the same type of slot pattern on the underside, but then they have a mirrored design, as can clearly be seen in Figure 4. This pattern then continues to achieve a homogeneous appearance.

Furthermore, a means (not shown), such as a fan, is present for generating an excess pressure within the applicator unit 3, so that dirt and the like cannot penetrate into the applicator unit.

All components are calculated in such a way that the radiation is guided and distributed in the best possible way. It is noted here that due to the number of eight wave pipes 16, the radiation is directed into the ground virtually parallel and without stray fields.

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For the sake of simplicity of drawing, all wiring and power supplies for operating the emission device have been omitted. These are generally known to a person skilled in the art with normal skill in the art and need no further clarification. Furthermore, for the sake of simplicity of the drawing, some elements are not shown in the Figures, which are, however, discussed below.

Any undesired reflections are prevented by providing a front reflection device and / or a rear reflection device in the normal direction of travel of the vehicle, the reflection device being intended for reflecting microwaves. Such a reflection device can comprise a U-shaped profile, the open end of the profile facing the ground. A highly effective way to prevent unwanted reflections uses two adjacent U-shaped profiles, with the open ends of the profiles facing the ground. A rear hinged drag plate 20, viewed in the normal direction of travel, prevents objects from being inserted under the emission device in an undesirable manner. The towing plate can be provided with a means, such as for instance a spring, for pressing a towing part of the towing plate against the ground.

Particularly, but not exclusively, in an embodiment of an assembly in which the applicator unit is mounted so as to be movable in height relative to the vehicle, side reflection devices are advantageous in order to prevent microwaves 30 sideways from the assembly when the assembly is undesirably lifted. are broadcasted. The reflecting device can comprise a number of juxtaposed, hanging reflecting means, in particular wires, metal wires or chains. In particular, the reflection device is made of stainless steel. A sensor is herein provided for measuring the distance from the bottom of an applicator unit to the ground, and for switching the microwave source on and off, respectively, in dependence on the measured distance. In order to prevent fouling of the applicator unit, the applicator unit is provided with a microwave-transparent plate, for example of ceramic, for closing the mouths of the corrugated pipes directed towards the ground. A sensor for measuring the intensity of microwave radiation outside the emission device can also be provided, which sensor is also used for switching the microwave source on and off, respectively, in dependence on the measured radiation. In particular, four sensors are each arranged at a corner of the applicator unit.

The above-mentioned assembly is used according to the invention in the following manner for sterilizing solid soil in a greenhouse with the aid of microwaves. The greenhouse has a rear wall and a path opposite the rear wall, over which the vehicle can be moved. The vehicle is moved from the path to the rear wall 20 so that the front of the applicator unit comes into contact with the rear wall of the greenhouse or is close to the rear wall. The microwave source is switched off during this movement. Thereafter, the vehicle is moved from the back wall back to the path 25, during which back movement the microwave source is switched on to sterilize the ground. When the vehicle has reached the path again, it is moved sideways to adjacent the part of the ground just treated with microwaves. After this, the vehicle is moved over the untreated soil to the rear wall, the microwave source being switched off. Afterwards the reverse displacement is repeated with the microwave source switched on. The speed of movement of the vehicle with the microwave source switched on is selected in dependence on measurement results that are carried out by means of DNA multiscans of soil prior to microwave treatment 13 and the measurement results of that soil after microwave treatment. Such DNA multi-scans can be performed in advance to determine an indication of the soil and the type and amount of nematodes, fungicides, insect unwanted seeds, and weeds and the like. Depending on these measurement results, an adjustment of the assembly can then take place experimentally in order to obtain an optimum sterilization result.

It will be clear that although the invention has been described as a combination of emission device and vehicle, the invention also relates to an emission device for emitting microwaves into the ground per se. Such an emission device can be provided with per se known mounting means for mounting the emission device on any vehicle, so that the emission device is movable over the ground.

The above description is included to illustrate the operation of preferred embodiments of the invention, and not to limit the scope of the invention. Starting from the above explanation, many variations will be evident to those skilled in the art that fall within the spirit and scope of the present invention, in particular as defined by the appended claims.

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Claims (25)

An assembly for microwave sterilization of solid soil, comprising an emission device for emitting microwaves into the soil and a vehicle for moving the emission device over the soil, the emission device being provided with a microwave source, wherein the microwave source is connected via a waveguide to an applicator unit arranged at the free end of the waveguide, the applicator unit comprising a number of corrugated pipes placed transversely to the normal direction of travel of the vehicle, wherein in the waveguide a distributing corrugated pipe is included for distributing the microwaves emitted from the microwave source over the corrugated pipes, wherein each corrugated pipe has a ground-facing mouth. Assembly according to claim 1, wherein the number of corrugated pipes placed next to each other is at least eight. 3. Assembly as claimed in claim 1 or 2, wherein each corrugated pipe is elongated, and the longitudinal direction of a corrugated pipe is situated substantially in the normal driving direction of the vehicle. 4. Assembly as claimed in any of the foregoing claims, wherein the mouth of a corrugated pipe comprises two slots. Assembly according to claim 4, wherein the slots are situated at an equal but opposite angle to the normal driving direction of the vehicle. An assembly according to any one of the preceding claims, wherein the distributing corrugated pipe is located substantially 1033105 transversely of the normal driving direction of the vehicle. 7. Assembly as claimed in claim 6, wherein the distributing corrugated pipe is provided with adjacent coupling slots for coupling microwaves in the respective corrugated pipe. An assembly according to claim 7, wherein the coupling slots are elongated and are located transversely of the normal driving direction of the vehicle. Assembly according to claim 7 or 8, wherein the coupling slots are staggered alternately. 10. Assembly as claimed in any of the foregoing claims, wherein the emission device is provided with a means for generating an overpressure in the applicator unit. An assembly according to any one of the preceding claims, wherein the emission device comprises two applicator units placed one behind the other in the normal direction of travel of the vehicle. An assembly according to any one of the preceding claims, wherein the microwave source is suitable for generating microwaves with a frequency of approximately 915 MHz. 13. Assembly as claimed in any of the foregoing claims, wherein in the normal driving direction of the vehicle a front reflection device and / or a rear reflection device is provided, wherein the reflection device is intended for reflecting microwaves. 14. Assembly as claimed in claim 13, wherein a reflection device comprises a U-shaped profile, wherein the open end of the profile faces the ground. 15. Assembly as claimed in claim 13 or 14, wherein the reflection device comprises two adjacent U-shaped profiles, wherein the open ends of the profiles 35 are directed towards the ground. An assembly according to any one of the preceding claims, wherein a rear hinged towing plate is provided, viewed in the normal direction of travel, which is provided with a means for pressing a towing part of the towing plate against the ground. 17. Assembly as claimed in any of the claims 13-15, wherein the reflection device comprises a number of juxtaposed, hanging reflection means, in particular wires, metal wires or chains. 18. Assembly as claimed in any of the claims 13-17, wherein the reflection device is made of stainless steel 10. An assembly according to any one of the preceding claims, wherein an applicator unit is height-adjustable. 20. Assembly as claimed in claim 19, wherein the emission device is provided with a sensor for measuring the distance from the bottom of an applicator unit to the ground, and for switching the microwave source on and off depending on the measured distance . An assembly as claimed in any one of the preceding claims, wherein the emission device is provided with a microwave-transparent plate, for example of ceramic, for closing off the corrugated pipes' mouths. 22. Assembly as claimed in any of the foregoing claims, wherein the assembly is provided with a sensor for measuring the intensity of microwave radiation outside the emission device, and for switching the microwave source on and off in dependence on the measured radiation, wherein in particular four sensors are each arranged at a corner of the applicator unit. 23. An emission device for emitting microwaves in the ground intended for use in an assembly according to any one of the preceding claims, wherein the emission device comprises the measures relevant to the emission device according to one of the preceding claims, wherein the emission device is provided with mounting means for mounting the emission device on a vehicle, so that the emission device is movable over the ground. A method for using microwaves to sterilize solid soil in a greenhouse, which greenhouse has a rear wall and a path opposite the rear wall, in which method an assembly according to any of claims 1 to 22 is used, which method 10 comprises the steps of: a. Moving the vehicle from the path to the rear wall so that the front of the applicator unit comes into contact with the rear wall or is close to the rear wall, during which movement the microwave source is switched off, b. moving the vehicle from the rear wall back to the path, during which displacement the microwave source is switched on to sterilize the ground, c. when the vehicle has again reached the path, moving the vehicle sideways to adjacent the part of the ground just treated with microwaves, d. repeating step a) wherein the vehicle 25 is moved over untreated soil to the rear wall, and repeating step b. 25. Method according to claim 24, wherein the speed of movement of the vehicle with the microwave source switched on is selected in dependence on measurement results that are performed by means of DNA multiscans of soil prior to microwave treatment and the measurement results of that soil after microwave treatment. -o-o-o-o-o-o-o-1033105