The present disclosure relates to electric apparatus that is configured to attenuate plant growth by the application of electrical energy thereto.
In properties both commercial and domestic, it is common to kill or at least control the growth of unwanted plants, commonly referred to as weeds. Conventional methods include treatment with a pesticide or more particularly a herbicide. However, there is a growing concern over such treatment for environmental reasons and unwanted exposure of herbicides to humans and animals. Moreover, weeds are increasingly becoming naturally resistant so herbicides are becoming more and more ineffective. As a result of these numerous drawbacks, the use of herbicides is increasingly prohibited.
Consequently, there is a desire for alternative treatments, which do not include the above drawbacks. An example includes treatment by the application of electrical energy. U.S. Pat. No. 4,338,743 discloses a respective apparatus, wherein electrical energy is applied at 14.4 kV at about 60 Hz to plants. Such apparatus has failed to become widespread in the market over concern over safety. For example, the high voltage may be a risk to a person in proximity to a treated weed.
Moreover, such apparatus has been found to interfere with other electrical equipment proximal the apparatus, which has led to the apparatus not being certified for use in certain areas, e.g. on railway lines, proximal which there is sensitive electronic equipment that is used for signalling and communication on a railway system.
Therefore, in spite of the effort already invested in the development of said apparatus further improvements are desirable.
The present disclosure provides electrical apparatus to kill a plant or at least attenuate plant growth. The apparatus includes an electrical energy supply unit; an applicator unit comprising one or more applicator electrodes, and; a return unit comprising one or more return electrodes. The electrical energy supply unit is arranged to apply electrical energy through a transmission circuit comprising the or each applicator electrode and the or each return electrode and a plant.
In embodiments, the apparatus implements a Faraday enclosure (sometimes also referred to as Faraday cage or Faraday shield) arranged to block electromagnetic radiation emitted from the electrical energy.
By implementing a Faraday enclosure, the apparatus implements electromagnetic shielding to block electromagnetic radiation emitted from the electrical energy. In particular, it has been found that the electrical energy may include high-frequency noise, that emits the electromagnetic radiation. The noise may be introduced from components of the electrical energy supply unit, e.g. from one or more of: a waveform shaping system that can implement harmonics/ringing when forming waveforms in the electrical energy; a rectifier; a transformer. The noise may be introduced from electrical arcs, e.g. due to electron movement in the plasma of the arc that emits wideband electromagnetic magnetic radiation. This high frequency noise has been found to emit electromagnetic frequency that can interfere with electrical componentry proximal the apparatus, e.g. componentry of railway systems for signalling or communications. Such interference may prohibit the use of electrical apparatus to kill plants proximal areas where there is sensitive electrical equipment, e.g. railway systems and highways. The Faraday enclosure has been found to be particularly effective in attenuating this electromagnetic radiation.
In embodiments, the Faraday enclosure is arranged to block electromagnetic radiation emitted from the electrical energy proximal to and through the or each applicator electrode and/or the or each return electrode.
As used herein the term “proximal to” in respect of an electrode (the applicator or return electrode) may refer to one or more of: the electrical energy transmitted through the transmission circuit between the applicator electrode and plant, including as an electrical arc; the electrical energy transmitted through the transmission circuit between the return electrode and plant, including as an electrical arc; the electrical energy transmitted within a predetermined radii of an electrode, which may be 1 m or 50 cm or 20 cm or 10 cm.
By implementing the Faraday enclosure to attenuate the electromagnetic radiation from the electrical energy as it travels through to one or more of: through the applicator electrode; to the plant from the applicator electrode; through the plant; though the return electrode; and any other portions of the transmission circuit between the applicator electrode and return electrode that are above the ground, the amount of electromagnetic radiation emitted from the apparatus is reduced.
In embodiments, the frequency of the electrical energy supplied to the plant is above 25 Hz and less than 1 MHz or 0.5 MHz.
In embodiments, the Faraday enclosure is arranged to block electromagnetic frequencies of: 30 MHz-6 GHz so that they are below 60 or 50 or 40 dB (μV/m) when measured 10 m away from the applicator electrode or the return electrode by a spectrum analyser. By implementing the Faraday enclosure to block electromagnetic frequencies of this range, it has been found that limited interference is provided to electrical equipment proximal a railway line or a highway. As used herein the term “proximal” in respect of a railway or highway may refer to a position within 10 or 5 or 2 meters of a railway line.
With such apparatus, it has surprisingly been found that a large amount of noise, e.g. from electrical arcing, in the region of 30 MHz-6 GHz is created from the substantially lower frequency electrical energy that is applied through the transmission circuit in the region of 25 Hz and less than 1 MHz. Hence by implementing the Faraday enclosure to attenuate this much higher frequency, electrical components proximal the treatment area may be protected.
In embodiments, the Faraday enclosure is arranged to block electromagnetic frequencies of 30 to 230 MHz so that they are below 60 or 50 or 40 dB (μV/m) when measured 10 m away from the applicator electrode or the return electrode, and/or: 230 MHz to 6 GHz so that they are below 60 or 50 or 40 dB (μV/m) when measured 10 m away from the applicator electrode or the return electrode.
In embodiments, the Faraday enclosure is formed of a material with a magnetic relative permeability of at least 0.99 or 0.99 to 1,000,000 (dimensionless). In embodiments, the Faraday enclosure is formed of a material with an electrical resistivity of less than 500,000×10−8 Ω·m or 1.5×10−8 to 500,000 10−8 106 ·m. By implementing a material with a magnetic relative permeability and electrical resistivity of these ranges, it has been found that the Faraday enclosure can block electromagnetic radiation such that limited interference is provided to electrical equipment proximal a railway line or a highway.
In embodiments, the thickness (t) in m of the Faraday enclosure is defined by the relationship:
t>3D, in particular t>5D,
wherein
F is the frequency in Hz, P is the magnetic permeability in H/m, which is calculated by multiplying the relative magnetic permeability μr (dimensionless) by the permeability constant μ0 in H/m, and C is the electrical conductivity in S/m. In embodiments wherein the Faraday enclosure is arranged as multiple layers, the thickness t can be the aggregated thickness of the individual layers. It has been found that a thickness within this range provides suitable blocking of the electromagnetic radiation emitted from the apparatus.
In embodiments, the material of the Faraday enclosure has a thickness of 0.01 mm to 10 mm or 0.05 mm to 5 mm or 0.1 mm to 3 mm.
In embodiments, the material is metal based, and may include one or more of: copper; brass; nickel; gold; silver; steel; tin; permalloy; aluminium; ferrite; supermalloy; stainless steel; other metal based material. In embodiments, the material is non-metal based, and may include one or more of: carbon (in particular as graphite, carbon nanotubes, and/or carbon fibre); silicon carbide; conductive paints (which may include metal particles); other conductive or semi-conductive materials.
In embodiments, the Faraday enclosure is arranged with a first layer and a second layer. By implementing multiply layers, blocking of the electromagnetic radiation may be optimised, for example, for the first layer a particular material (e.g. including tin, permalloy or supermalloy) may be selected to block lower frequencies, and for the second layer a particular different material (e.g. including copper or aluminium or brass) may be selected to block higher frequencies.
In embodiments, a gap is arranged between the first layer and second layer. The gap may be 0.25 mm to 100 mm, or 0.5 mm to 50 mm or 2-8 mm. The gap may be occupied by air or a vacuum or other material. By implementing a gap the electromagnetic radiation has two absorptions (i.e. through the first layer and second later) and four reflections (i.e. there are four layer/air interfaces) as opposed to one absorption and two reflections that may be achieved by an equivalent single layer. This may have an enhanced effect in reducing the amount of electromagnetic radiation that is transmitted though the Faraday enclosure.
In embodiments, a carrier is implemented to carry the Faraday enclosure. The carrier may be implemented as a layer (e.g. the first layer and optional second layer are connected to the carrier layer). Alternatively, the second layer may be implemented as the carrier layer. In embodiments, an electrically insulating material (including glass fibre) is implemented as the carrier. By implementing the carrier, the Faraday enclosure may be structurally supported and protected from damage.
In embodiments, the carrier layer is arranged as an exterior layer such that the Faraday enclosure is not visible from an exterior of the apparatus. By implementing the carrier layer to form an exterior surface of the apparatus the Faraday enclosure is not externally visible.
In embodiments, electrical circuity is arranged to electrically connect the Faraday enclosure to the ground. By connecting the Faraday enclosure to the ground, electrical energy that contacts the Faraday enclosure (e.g. by means of electrical arcs or sparking) can be transmitted through the Faraday enclosure and into the ground. It may then be transferred through the ground to the return electrode and back to the transmission circuit. Accordingly, the electric energy that leaks in this way is safely returned to the transmission circuit.
In embodiments, a Faraday earth electrode is arranged to physically contact the ground, the Faraday earth electrode electrically connected by the electrical circuitry to the Faraday enclosure. As used herein the term “physically contact the ground” may refer to an electrode that is configured to rest on and/or insert into the ground such that an electrically conductive connection is made.
In embodiments, the Faraday enclosure is isolated (e.g. it is not physically connected to the ground) from the ground.
In embodiments, the Faraday enclosure is electrically isolated from the transmission circuit. By electrically isolating the Faraday enclosure from the transmission circuit, the electrical energy of the transmission circuit is less likely to arc, spark or otherwise short to the Faraday enclosure than to a plant.
In embodiments, the Faraday enclosure is arranged to substantially surround the applicator electrode and/or the return electrode. As used herein the term “substantially surround” in respect of the electrode may refer to the electrode being covered so that it is not visible in normal use, e.g. the electrode may be covered when viewed from all angles except the bottom (where a treatment mouth may be located), which in normal use is blocked by the ground. Substantially surround may refer to the Faraday enclosure extending around the electrodes, e.g. on at least two sides thereof.
In embodiments, the Faraday enclosure is arranged with a treatment mouth to receive a plant for treatment. By implementing a treatment mouth that is arranged to receive plants that extend from the ground, plants can enter the Faraday enclosure for treatment with the electrical energy.
In embodiments, (e.g. except for the portion of the Faraday enclosure that comprises the treatment mouth) the Faraday enclosure is arranged to entirely enclose the or each applicator electrode and the or each return electrode without there being a gap or aperture greater than 50 cm or 25 cm diameter or 10 cm (or the equivalent area for a non-circular aperture) or there are no gaps. By implementing a Faraday enclosure without substantial gaps being greater than the gaps as defined by these ranges, suitable blocking of the electromagnetic radiation may be provided.
In embodiments, the Faraday enclosure includes a movable portion which is movable to facilitate insertion of a plant into the treatment mouth. By implementing a movable portion, e.g. a flexible or pivoted portion, the Faraday enclosure can be adapted so that plants are more conveniently received in the treatment mouth.
In embodiments, a movable portion is arranged to facilitate insertion of the plant into the treatment mouth. The movable portion may facilitate said insertion as the or each applicator electrode is moved in a treatment direction, e.g. the movable portion is arranged on a front surface of the Faraday enclosure that is perpendicular to the treatment direction.
In embodiments, the Faraday enclosure is arranged to extend along the ground. By having the Faraday enclosure extend across the ground the surface area of the treatment mouth may be minimised to enhance blocking of electromagnetic radiation. As used herein the term “along the ground” may refer to a substantial portion (e.g. a plate or flap) that is aligned to the ground in use (rather than, for example, an edge of a side portion of the Faraday enclosure).
In embodiments, the Faraday enclosure is arranged to cover the applicator and/or return electrode when viewed perpendicular to one or more of the following viewing planes: a viewing plane that is above the Faraday enclosure/apparatus and parallel to a surface that the apparatus is arranged on; a viewing plane, which is defined by a vector parallel to a direction of treatment along which the applicator electrode is moved during treatment and a vector which is perpendicular to a surface that the apparatus is arranged on, and; a viewing plane, which is normal to a vector parallel to a direction of treatment along which the applicator electrode is moved during treatment. As used herein the term “cover” in respect of the electrode may refer to the material of the Faraday enclosure overlapping the electrode when it is viewed from the relevant plane, e.g. so that it is not visible.
In embodiments, a material of the Faraday enclosure is arranged as a Faraday shield with a continuous covering of electrically conductive material.
In embodiments, a material of the Faraday enclosure is arranged as a Faraday cage with a covering of electrically conductive material that comprises a plurality of apertures. In embodiments, the aperture sizes are: 0.1 mm to 60 mm, or 0.25 mm to 40 mm, 0.5 mm to 20 mm. By implementing apertures, the Faraday enclosure may be light weight whilst retaining sufficient blocking of the electromagnetic radiation. It may also be possible to visualise a treatment process from external to the Faraday enclosure, e.g. to check for arcing and/or fire.
The present disclosure provides a vehicle comprising the apparatus of any preceding claim. The vehicle may be suitable for running on rails of a railway system, wherein the applicator electrode is arranged to apply the electrical energy to a plant proximal the rails. The vehicle may be suitable for running on roads of a highway system, wherein the applicator electrode is arranged to apply the electrical energy to a plant proximal the road. The vehicle may be suitable for running on fields, wherein the applicator electrode is arranged to apply the electrical energy to a plant arranged in the field.
The present disclosure provides use of the apparatus as disclosed herein for treatment of a plant, e.g. to kill or weaken the plant. The use may implement any feature of the preceding embodiments or another embodiment disclosed herein.
The present disclosure provides a method of treating a plant with electrical energy. The method comprises applying electrical energy to a plant and blocking with a Faraday enclosure electromagnetic radiation emitted from the electrical energy. The method may comprise applying electrical energy to the plant whilst moving along rails of a railway system or moving along a road of a highway system. The method may implement any feature of the preceding embodiments or another embodiment disclosed herein.
The preceding summary is provided for purposes of summarizing some embodiments to provide a basic understanding of aspects of the subject matter described herein. Accordingly, the above-described features are merely examples and should not be construed to narrow the scope or spirit of the subject matter described herein in any way. Moreover, the above and/or proceeding embodiments may be combined in any suitable combination to provide further embodiments. Other features, aspects, and advantages of the subject matter described herein will become apparent from the following Detailed Description, Figures, and Claims.
Aspects, features and advantages of embodiments of the present disclosure will become apparent from the following description of embodiments in reference to the appended drawings in which like numerals denote like elements.
Before describing several embodiments of the apparatus, it is to be understood that the system is not limited to the details of construction or process steps set forth in the following description. It will be apparent to those skilled in the art having the benefit of the present disclosure that the system is capable of other embodiments and of being practiced or being carried out in various ways.
The present disclosure may be better understood in view of the following explanations:
As used herein, the term “railway system” may refer to a system comprising a network of rails located on tracks for wheeled vehicles running on the rails for transferring passengers and goods. It may include various systems for electrical power transmission, signalling, communication etc.
As used herein, the term “highway system” may refer to a system comprising a network of roads for wheeled vehicles running on the roads for transferring passengers and goods. It may include various systems for electrical power transmission, signalling, communication etc.
As used herein, the term “vehicle” may refer to a machine that is capable of traveling on various mediums including: rails; roads; fields; or other medium.
As used herein, the term “ Faraday enclosure” or “electromagnetic shielding” may refer to an arrangement of material that when an interior of the enclosure is exposed to an electrical field (e.g. electromagnetic radiation) it causes electric charges within the material to be distributed so that the charges cancel the effect of the electrical field effect external the enclosure.
As used herein, the term “block” or “attenuate” may refer to a full or substantial reduction of propagated electromagnetic radiation by the Faraday enclosure.
As used herein, the term “plant” or “weed” may refer to an undesired plant in a human controlled setting, such as a farm field, garden, lawn or park. A weed may refer to a multicellular photosynthetic eukaryote.
As used herein, the term “electrical arc” or “arc” may refer to an electrical breakdown of a gas that produces an electrical discharge. An arc is formed by an electrical current through a normally nonconductive medium such as air, and is characterized by a plasma, which may produce visible light. An arc discharge is characterized by a lower voltage than a glow discharge and relies on thermionic emission of electrons from the electrodes supporting the arc.
As used herein, the term “electrical energy” or “processed electrical energy” may refer to electrical energy supplied by an electrical energy supply unit and applied to the plant, e.g. though a transmission circuit. The electrical energy may comprise a periodic or aperiodic waveform, i.e. a waveform that continuously repeats with the repeating units therein having a constant or a varying period, e.g. a pulsed wave with a fixed duty cycle or a varying duty cycle. The shape of the repeating unit may be one of or a combination of one or more of the following forms: sine wave; saw-tooth wave; triangular wave; square wave; pulsed, e.g. DC pulsatile, half-wave rectified; other known form. The exact shape of the repeating unit may be an approximation of one of the aforesaid forms for reasons of distortion, e.g. overshoot/undershoot and the associated ringing and settle time. The repeating unit may be positive or negative or a combination thereof with respect to a selected reference value, which is typically earth or the 0 V of the voltage supply but may be another positive or negative voltage level. The frequency of the waveform may be above 25 Hz, above 1 khz, above 10 kHz, above 18 kHz or above 25 kHz. The maximum frequency may be 1 mHz. The peak voltage may be of at least 1 kV, and may have a maximum of 70 kV. The electrical current may be of at least 10 mA rms, and may have a maximum of 250A. With such a current and voltage applied though a transmission circuit that includes the plant, the water present plant may in effect be vaporized by the electrical energy, which can cause substantial cellular damage to the plant. This damage may in particular be exacerbated at high frequency in, inter alia, the Xylem and phloem. It will be understood that when referring to the voltage of the electrical energy, when the electrical energy has a waveform, the voltage is in respect of a suitable quantity, such as RMS, peak or other. The same applies for other electrical quantities such as power and current.
As used herein, the term “electrical energy supply unit” may refer to any unit or system, including a distributed system, for generating and/or conditioning electrical energy for supply to a transmission circuit which, in use, incorporates a plant.
As used herein, the term “electrical circuitry” or “electric circuitry” or “electronic circuitry” or “circuitry” or “control circuitry” may refer to, be part of, or include one or more of the following or other suitable hardware or software components: an Application Specific Integrated Circuit (ASIC); electronic/electrical circuit (e.g. passive electrical components, which may include combinations of transistors, transformers, resistors, capacitors); a processor (shared, dedicated, or group); a memory (shared, dedicated, or group), that may execute one or more software or firmware programs; a combinational logic circuit. The electrical circuitry may be centralised on the apparatus or distributed, including distributed on board the apparatus and/or on one or more components in communication with the apparatus, e.g. as part of the system. The component may include one or more of a: networked-based computer (e.g. a remote server); cloud-based computer; peripheral device. The circuitry may be implemented in, or functions associated with the circuitry may be implemented by, one or more software or firmware modules. The circuitry may include logic, at least partially operable in hardware.
As used herein, the term “processor” or “processing resource” may refer to one or more units for processing including an ASIC, microcontroller, FPGA, microprocessor, digital signal processor (DSP) capability, state machine or other suitable component. A processor may include a computer program, as machine readable instructions stored on a memory and/or programmable logic. The processor may have various arrangements corresponding to those discussed for the circuitry, e.g. on-board and/or off board the apparatus as part of the system.
As used herein, the term “applicator unit” or “applicator” may refer to any suitable device for applying electrical energy to a plant, including by direct contact with the plant and/or spark transmission. In particular, an applicator electrode of the applicator unit may be arranged for direct contact with a portion of the plant above the ground.
As used herein, the term “earth unit” or “return unit” may refer to any suitable device for receiving electrical energy from a circuit including the plant and optionally the ground to complete a transmission circuit, including by direct contact with the plant and/or spark transmission. A return electrode of the return unit may be inserted into the ground, or arranged to rest on/be dragged along the surface of the ground, or otherwise electrically connected to the ground to receive the electrical energy transmitted through the above ground portion of the plant, and the ground surrounding the plan as part of the transmission circuit.
As used herein, the term “apparatus” or “electrical apparatus” may refer to any combination of one or more of the following for treatment of a plant: electrical energy supply unit; electrical circuitry; applicator unit; applicator electrode; return unit; return electrode; transmission circuit.
Referring to
The transmission circuit 12, when treating a plant, may include said plant 14. It will be understood that depending on the operative arrangement of the applicator unit and return unit, a return path of the transmission circuit 12 optionally includes other matter, such as proximal earth and fluid (e.g. air and moisture) to the plant.
The apparatus 2 includes electrical circuitry 16, which may implement a range of control operations. In embodiments, said circuitry 16 is operable to control the electrical energy supplied by the electrical energy supply unit 4 through the transmission circuit 12, as will be discussed.
Referring to
The applicator electrode 18 is adapted to apply the electrical energy 10 to the plant 14. In embodiments, the applicator electrode 18 is arranged for direct contact with the plant 14. As used herein “direct contact” may refer to physical contact between the plant and electrode, and may be achieved by operatively arranging the electrode to be exposed from a body of the applicator. The applicator electrode 18 comprises an electrically conductive material e.g. copper, zinc, bronze, brass, aluminium or steel.
The geometric configuration of the applicator electrode 18 may be selected depending on the intended treatment regimen, for example: a rod for sweeping through areas of dense plants; a hook-shape for separating plants.
The applicator unit 6 comprises body 20 to carry the applicator electrode 18. The body 20 may be adapted to be held by a user or fixed to a chassis depending on the particular configuration of the apparatus 2 (e.g. adapted for domestic or agricultural implementation respectively).
In embodiments, which are not illustrated, the applicator electrode is implemented as a plurality of electrodes, e.g. for treatment of multiple plants at a given moment.
Referring to
The return electrode 22 is adapted to provide a return for electrical energy 10 via the plant 14 to complete the transmission circuit 12. In embodiments, the return electrode 22 is arranged for direct contact with the ground 26 (shown in
The geometric configuration of the return electrode may be selected depending on the intended implementation of the apparatus, for example: an implement for insertion into the ground (e.g. for apparatus that in use remains in a generally fixed position), such as a rod or spike; an implement for movement along the ground (e.g. for apparatus that in use has a variable position), such as a rod or spike), such as a flat plate or roller, and; a combination of the aforesaid implementations.
The return unit 8 comprises body 24 to carry the return electrode 22. The body 24 may be adapted to be held by a user or fixed to a chassis depending on the particular configuration of the apparatus 2 (e.g. adapted for domestic or agricultural implementation respectively).
In embodiments, which are not illustrated, the return electrode is implemented as a plurality of electrodes, e.g. for treatment of multiple plants at a given moment.
Generally, the apparatus 2 is arranged with the return electrode 22 arranged in operative proximity to the applicator electrode 18. Operative proximity may refer to a geometric arrangement to limit the path of the electrical energy 10 through the ground 26, which may advantageous for reasons of efficient and/or electrical safety.
Referring to
The electrical energy supply unit 4 includes an electrical energy processing unit 32 for processing of the supply electrical energy 30 to the electrical energy 10. The electrical energy processing unit 32 includes an electrical transformer 34 with appropriately configured windings, e.g. for step-up or step down, depending on the configuration of the supply electrical energy 30 desired output of the electrical energy 10.
In variant embodiments, which are not illustrated, alternative step-up or step-down converters to the transformer are implemented, e.g. a boost converter, other amplifier topology. A step-up or step-down converter may also be obviated if the electrical energy is supplied in the desired form.
For example, the transformer may be obviated if the electrical energy is supplied in the desired form by: the power supply; or the power supply is replaced by an input unit to receive a commercial or domestic electrical supply (a mains supply).
Where the power supply 28 provides supply electrical energy 30 as AC (e.g. the power supply 28 is arranged as a generator) or the power supply 28 is omitted and there is an input unit comprising a circuit for receiving an electrical supply (e.g. from a mains electrical supply or other electrical supply) the electrical energy processing unit 32 includes a AC to DC converter (not illustrated) arranged to provide a DC current to a waveform shaping system, which may be referred to as a switching system 33. Where the power supply 28 provides supply electrical energy 30 as DC, e.g. a battery, an AC to DC converter is obviously obviated.
The electrical energy processing unit 32 includes a switching system 33 to generate the desired wave form (e.g. in shape and/or frequency) in the electrical energy supplied to the electrical transformer 34. The switching system 33 is implemented as an electrically operated switch (e.g. a MOSFET, relay, other transistor).
In variant embodiments of the electrical energy supply unit, which are not illustrated, the power supply (or electrical supply to the input unit) supplies electrical energy of the desired configuration. Accordingly, the electrical energy processing unit is obviated. In other embodiments, the power supply (or input unit) supplies electrical energy which only needs step-up or step-down, in which case the switching system is obviated but the transformer is maintained. In other examples the switching system is present but the step-up or step-down converter is omitted.
The electrical circuitry 16 is implemented to control the electrical energy 10, through the transmission circuit 12. Said control may implement control of one or more of the following electrical quantities: electrical potential between the applicator and return electrodes; electrical current control; frequency or duty control; phase.
In the embodiment of
Referring to
The Faraday enclosure 40 is arranged to block the electromagnetic radiation emitted from the electrical energy 10 as it travels through a portion of the transmission circuit 12 that comprises: through the applicator electrode 18; between the applicator electrode 18 and the return electrode 8, and; through the return electrode 22. The portion of the transmission circuit 12 that comprises between the applicator electrode 18 and the return electrode 8 includes through a plant 14, when one is present and being treated (not illustrated in
Although the Faraday enclosure 40 encloses cabling (not illustrated) electrically connecting the electrical energy 10 to the applicator electrode 18 and the return electrode 22, the cabling is generally electromagnetically shielding cabling.
In variant embodiments, which are not illustrated, the Faraday enclosure is arranged to block electromagnetic radiation form the electrical energy through other portions of the transmission circuit, e.g. it may block the electrical energy through the applicator electrode and from the applicator electrode to the plant rather than the return portion.
As illustrated in
In variant embodiments, which are not illustrated, the Faraday enclosure is not physically connected by an electrode to the ground.
Referring to
Referring to
Referring to
In variant embodiments, which are not illustrated, the Faraday enclosure has more than two layers.
The thickness (t) in m of the Faraday enclosure 40 (e.g. the first layer 44 and the optional second layer 46) may be defined by the relationship:
t>3D, in particular t>5D,
wherein
F is the frequency in Hz, P is the magnetic permeability in H/m, which is calculated by multiplying the relative magnetic permeability μr (dimensionless) by the permeability constant μ0, H/m, and C is the electrical conductivity in S/m. Typically the thickness is 0.1 mm to 10 mm or 2 mm to 25 mm.
Referring to
In variant embodiments, which are not illustrated: the carrier is alternatively arranged to carry the Faraday enclosure, e.g. it may comprise mechanical fixings, including brackets; the first and/or second layer may be implemented as the carrier; the carrier can be arranged as an interior layer.
In the examples, the Faraday enclosure 40 is arranged as a Faraday shield with a continuous covering of the first layer 44, and in embodiments where present the second layer 46.
In variant embodiments, which are not illustrated, the Faraday enclosure is arranged as a Faraday cage with the first layer (and in embodiments where present the second layer), having a plurality of apertures. The apertures can be: 0.1 mm to 60 mm, or 0.25 mm to 40 mm, 0.5 mm to 20 mm in diameter.
In both examples of a continuous Faraday shield or enclosure or a Faraday cage with apertures, the Faraday enclosure is arranged to enclose the applicator electrodes 18 and return electrodes 22, without there being a gap of aperture greater than 50 mm in diameter or the equivalent area for a non-circular shape.
Referring to
The Faraday enclosure 40 is arranged to enclose applicator and return electrode pairs 18, 22. The Faraday enclosure 40 is arranged as a skirt 68 that extends from a carrier 70 to (including proximal to or to abut) the ground 26.
The Faraday enclosure 40 includes a treatment mouth 72 to receive a plant 26. There are no other gaps in the Faraday enclosure 40 (excluding those that may implement a Faraday cage, which is discussed later on). As the vehicle 52 moves in the longitudinal direction 100 the plant 26 can enter the treatment mouth 72 or is arranged proximal thereto.
It will be appreciated that the Faraday enclosure 40 can be comprised of portions of the apparatus 2 and/or vehicle 52 when they are composed of an appropriate material (e.g. a chassis or housing) that provides the effect of attenuating the electromagnetic radiation. There is no need to supplement these portions with additional material to form the Faraday enclosure 40, e.g. additional material can be filled in around any gaps to maintain the continuous nature of the Faraday enclosure 40.
The Faraday enclosure 40 therefore surrounds all sides and the top of the electrode pairs 18, 22, such that they are entirely overlapped by the Faraday enclosure 40 when viewed in all directions except the height direction 104, e.g. from underneath the vehicle 52. In this way there is no direct line of sight between the electrode pairs 18, 22 and electrical equipment (not illustrated in
The electrode pairs 18, 22 are therefore overlapped by the Faraday enclosure 40, when viewed perpendicular to the following planes: a viewing plane that is above and parallel to a surface 26 that the apparatus is arranged on; a viewing plane normal to the longitudinal direction 100; a plane normal the lateral direction 102.
Referring to
In variant embodiments, which are not illustrated: the ground extending member is alternatively arranged, e.g. as a rigid plate; ground extending member is omitted.
Referring to
In variant embodiments, which are not illustrated: the movable front portion is made from a rigid material which is pivotably connected to the vehicle; the movable portion is omitted; other portions of the Faraday enclosure are implemented as movable, including the back portion (not illustrated) which is arranged opposed the front portion.
Referring to
The Faraday enclosure 40 is arranged to enclose applicator and return electrode pairs 18, 22. The Faraday enclosure 40 is arranged as a skirt 68 that extends from a carrier 70 to (including proximal to or to abut) the ground 26.
The Faraday enclosure 40 includes a treatment mouth 72 to receive a plant 26. There are no other gaps in the Faraday enclosure 40 (excluding those that may implement a Faraday cage, which is discussed later on). As the vehicle 52 moves in the longitudinal direction 100 the plant 26 can enter the treatment mouth 72 or is arranged proximal thereto.
It will be appreciated that the Faraday enclosure 40 can be comprised of portions of the apparatus 2 and/or vehicle 52 when they are composed of an appropriate material (e.g. a chassis or housing) that provides the effect of attenuating the electromagnetic radiation. There is no need to supplement these portions with additional material to form the Faraday enclosure 40, e.g. additional material can be filled in around any gaps to maintain the continuous nature of the Faraday enclosure 40.
The Faraday enclosure 40 therefore surrounds all sides and the top of the electrode pairs 18, 22, such that they are entirely overlapped by the Faraday enclosure 40 when viewed in all directions except the height direction 104, e.g. from underneath the vehicle 52. In this way there is no direct line of sight between the electrode pairs 18, 22 and electrical equipment (not illustrated in
The electrode pairs 18, 22 are therefore overlapped by the Faraday enclosure 40, when viewed perpendicular to the following planes: a viewing plane that is above and parallel to a surface 26 that the apparatus is arranged on; a viewing plane normal to the longitudinal direction 100; a plane normal the lateral direction 102.
The Faraday enclosure 40 includes a movable front portion 76, which is movable to facilitate insertion of the plant 14 into the treatment mouth 72. The front portion 76 is made from a flexible material, including a thin metal layer deposited on a flexible carrier layer, such as rubber.
In variant embodiments, which are not illustrated: the movable front portion is made from a rigid material which is pivotably connected to the vehicle; the movable portion is omitted; other portions of the Faraday enclosure are implemented as movable, including the back portion (not illustrated) which is arranged opposed the front portion; a ground extending member may be implemented as discussed for the rail vehicle embodiment.
Referring to
In variant embodiments, which are not illustrated, the Faraday enclosure is alternatively shaped, including: hemispherical; frustoconical; other shape.
It will be appreciated that any of the disclosed methods (or corresponding apparatuses, programs, data carriers, etc.) may be carried out by either a host or client, depending on the specific implementation (i.e. the disclosed methods/apparatuses are a form of communication(s), and as such, may be carried out from either ‘point of view’, i.e. in corresponding to each other fashion). Furthermore, it will be understood that the terms “receiving” and “transmitting” encompass “inputting” and “outputting” and are not limited to an RF context of transmitting and receiving radio waves. Therefore, for example, a chip or other device or component for realizing embodiments could generate data for output to another chip, device or component, or have as an input data from another chip, device or component, and such an output or input could be referred to as “transmit” and “receive” including gerund forms, that is, “transmitting” and “receiving”, as well as such “transmitting” and “receiving” within an RF context.
As used in this specification, any formulation used of the style “at least one of A, B or C”, and the formulation “at least one of A, B and C” use a disjunctive “or” and a disjunctive “and” such that those formulations comprise any and all joint and several permutations of A, B, C, that is, A alone, B alone, C alone, A and B in any order, A and C in any order, B and C in any order and A, B, C in any order. There may be more or less than three features used in such formulations.
In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. The word ‘comprising’ does not exclude the presence of other elements or steps then those listed in a claim. Furthermore, the terms “a” or “an,” as used herein, are defined as one or more than one. Also, the use of introductory phrases such as “at least one” and “one or more” in the claims should not be construed to imply that the introduction of another claim element by the indefinite articles “a” or “an” limits any particular claim containing such introduced claim element to inventions containing only one such element, even when the same claim includes the introductory phrases “one or more” or “at least one” and indefinite articles such as “a” or “an.” The same holds true for the use of definite articles. Unless stated otherwise, terms such as “first” and “second” are used to arbitrarily distinguish between the elements such terms describe. Thus, these terms are not necessarily intended to indicate temporal or other prioritization of such elements. The mere fact that certain measures are recited in mutually different claims does not indicate that a combination of these measures cannot be used to advantage.
Unless otherwise explicitly stated as incompatible, or the physics or otherwise of the embodiments, example or claims prevent such a combination, the features of the foregoing embodiments and examples, and of the following claims may be integrated together in any suitable arrangement, especially ones where there is a beneficial effect in doing so. This is not limited to only any specified benefit, and instead may arise from an “ex post facto” benefit. This is to say that the combination of features is not limited by the described forms, particularly the form (e.g. numbering) of the example(s), embodiment(s), or dependency of the claim(s). Moreover, this also applies to the phrase “in one embodiment”, “according to an embodiment” and the like, which are merely a stylistic form of wording and are not to be construed as limiting the following features to a separate embodiment to all other instances of the same or similar wording. This is to say, a reference to ‘an’, ‘one’ or ‘some’ embodiment(s) may be a reference to any one or more, and/or all embodiments, or combination(s) thereof, disclosed. Also, similarly, the reference to “the” embodiment may not be limited to the immediately preceding embodiment.
As used herein, any machine executable instructions, or compute readable media, may carry out a disclosed method, and may therefore be used synonymously with the term method, or each other.
The foregoing description of one or more implementations provides illustration and description, but is not intended to be exhaustive or to limit the scope of the invention to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practice of various implementations of the present disclosure.
2 Electrical apparatus
14 Plant
26 Ground
Number | Date | Country | Kind |
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20197649.5 | Sep 2020 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2021/076056 | 9/22/2021 | WO |