NL1038724C2 - METHOD AND DEVICE FOR A GAS DISCHARGE LAMP AS THE ELECTRODE FOR THE PRODUCTION OF OZONE OR RADICALS. - Google Patents

Description

Method and device for a gas discharge lamp as an electrode for the production of ozone or radicals

The present invention relates to a method and device for a gas discharge lamp as an electrode for the production of ozone or radicals, characterized by a power supply which can be connected to the mains and which supplies a rectified high voltage of, for example, 300 volts and / or a rectified low voltage of, for example, 24 volts, means for generating a pulsed alternating voltage or a pulsed direct voltage, at least one amplifier for amplifying the alternating voltage and / or the pulsed direct voltage, a (high-voltage) transformer with at least a primary 10 and a secondary winding, a first coil which at least partially wound around a first gas discharge lamp or whose generated (electro) magnetic field extends to the gas in the first gas discharge lamp, a second coil which is at least partly wound around a second gas discharge lamp or whose generated (electro) magnetic field extends extends to the gas in d the second gas discharge lamp in which only one connection of the first coil is galvanically connected to the (high-voltage) transformer and in which also only one connection of the second coil is galvanically connected to the output of the high-voltage transformer and wherein between the first and the second gas discharge lamp corona is created that leads to the production of ozone.

20 Introduction

In public buildings, business premises, factory halls, garages, sheds and homes, good lighting is essential. Given the increasing social importance of sustainable lighting, there is a growing need for alternatives to the incandescent lamp that produces only a low light output per Watt of power consumed.

According to the prior art, good alternatives are the fluorescent lighting and the LED lamp. Due to the relatively high cost price of the LED lamp and the problems associated with LED technology, such as a limited light spectrum and a multiple of shadows due to the use of a large number of LEDs, gas discharge lamps are preferable to LEDs in many applications.

According to prior art, use is also made of gas discharge lamps (UVC lamps) for disinfection purposes. UV LEDs are also available according to the state of the art, but these have a very high cost price, a low efficiency, a short lifespan and a small capacity. Gas discharge lamps are also used in sunbed systems.

According to the state of the art, lighting by means of fluorescent tubes is usually controlled with an alternating voltage of 50 Hz. By placing a choke as an inductive load in series with the fluorescent lamp, the power of the fluorescent lamp is regulated.

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The fluorescent lamp is switched on with a starter intended for this purpose. A filament is heated with the circuit until it has reached a desired temperature, after which gas discharge is generated with a voltage pulse. After this the fluorescent lamp starts. A disadvantage of 50 Hz illumination is that the switching speed is so low that it is noticed by the human eye and is often perceived as a nuisance. In addition, the choke used in 50 Hz lighting dissipates a considerable amount of energy. High frequency controls of fluorescent lighting ensure that the fluorescent lighting does not cause any annoying flashing effects and are also more energy-efficient. In practice, however, 50 Hz drives are often used because they are cheaper.

10 There is a great need in the market for high-frequency drivers of gas discharge lamps that can be mass-produced at a low cost. With the technology according to the present invention, it is possible to produce high-frequency drivers of gas discharge lamps at a low cost.

A disadvantageous characteristic of conventional gas discharge lamps according to the prior art is that they are equipped with electrodes and with an incandescent coil. Another disadvantageous feature is that these gas discharge lamps contain mercury.

The present invention also relates to a method and device with which it is possible to control gas discharge lamps without using the glow coils present therein and without using the electrodes present therein. This means that existing gas discharge lamps such as fluorescent lamps and (JVC lamps and lamps that are placed in, but not limited to, a tanning bed) can be controlled in a new way whereby the electrodes and glow coils present are not used. The invention has the potential to produce gas discharge lamps which do not contain electrodes or filament. This means that the production process of the gas discharge lamps can be drastically simplified and that (JVC disinfection systems can be realized in a safer and simpler way compared to prior art. Finally, with the technology according to the present invention, a type of gas discharge lamp can be used as lighting that does not contain mercury, which not only provides a cost advantage but is, above all, sustainable and saves the environment.

It also appears to be possible to use the gas discharge lamps according to the technology of the present invention in the production of ozone. Ozone is used in practice for the disinfection of water and air. An ozone generator consists of a high voltage generator that preferably generates an alternating voltage with a frequency in the range of 1 Hz to 100 MHz and more preferably in the range of 1 kHz to 100 kHz. This high voltage is then operatively connected to specially designed electrodes whereby gas discharge occurs between the electrodes and a corona 3 is formed. Ozone is produced in the corona and at the same time an amount of UV radiation. A first major drawback of the electrodes according to the prior art is that they consist at least in part of metal which is subject to aging such as corrosion, evaporation or pitting. A second major disadvantage of the electrodes according to the prior art is that the design of these electrodes is expensive since a constant distance between the electrodes is essential for proper operation of the electrodes and the metal conductors must be accurately positioned in their housing . In this context, housing is understood to mean the dielectric that at least partially covers the electrodes. This dielectric often consists of glass, ceramic or composite material. A third major disadvantage of the prior art electrodes is that it is difficult to guarantee a minimum lifetime of the electrodes given that only a very small tolerance in geometry and material composition of the electrodes is acceptable for reliable operation.

With the technology according to the present invention it is possible to make gas discharge tubes as electrodes for ozone production, wherein the active part of these electrodes does not contain a metal conductor so that no corrosion can occur. Also, the tolerance in the geometry of the electrodes is much less critical with the technology according to the present invention than with the electrodes according to the prior art. Finally, by choosing the material of the electrodes according to the technology of the present invention, in practice usually glass or quartz, in combination with the production method of the electrodes, a minimum lifetime of the electrodes can be guaranteed with simple means.

The technology according to the present invention is also extremely suitable for use in combination with a device for wireless energy transfer. Such a device is described later in this application and contains as essential components a primary coil and a secondary coil between which energy transfer takes place through induction. The primary coil and the secondary coil preferably consist of coil wound coils mounted on a printed circuit board and / or cylindrical coils. In particular, wireless energy transfer by means of induction to UVC lamps or to devices for the production of ozone are commercially interesting because in this way inherently safe disinfection systems can be made that are extremely suitable for disinfecting water. Such systems are expressly part of the present invention.

Technical description of the present invention

According to a first aspect, the technology according to the present invention consists of a power supply. This power supply preferably receives its electrical energy from the mains or from a battery or from a solar cell or from a turbine including a windmill or from a microbial fuel cell. According to a second aspect, the present invention consists of a 4 microprocessor and / or microcontroller and / or PC, hereinafter referred to simply as a microprocessor, which alternately supplies a pulsed direct voltage such as a block voltage on at least 2 outputs. The frequency and optionally the amplitude of the pulsed direct voltage are software-adjustable and the clock speed of the microprocessor is preferably set by means of an external crystal. According to a third aspect, the present invention consists of a pre-amplifier which amplifies each of the (block) voltages supplied by the microprocessor. Such a preamplifier preferably consists of an NPN transistor such as a BC547B type transistor connected with the base to the output of the microprocessor, the emitter of which is connected to zero and the collector connected to the plus via a collector resistor . According to a fourth aspect, the present invention consists of a power amplifier which is supplied by the preamplifier. The power amplifier preferably consists of 2 FETs. The gate of each FET is connected to a channel of the preamplifier. For the coupling of the gate of the FETs to the preamplifier, optionally use is made of 2 resistors as a voltage divider and / or a coupling capacitor and / or a zener diode. The end result is that both FETs of the power amplifier are alternately switched on and off by the microprocessor. Preferably use is made of N FETs and a non-limiting example of suitable FETs are FFs of the IRF640 type. The drain of both FETs is connected to the primary winding of a (high-voltage) transformer equipped with a center tap. The center tap is connected to the plus of the power source. By alternately switching both FETs, an alternating voltage is generated on the secondary winding of the transformer. In short, the power amplifier works according to the push-pull principle. According to a fifth aspect, the technology according to the present invention consists of a first coil which is at least partly wound around the gas discharge lamp or whose generated magnetic field extends to the gas in the gas discharge lamp. According to a sixth aspect, the technology according to the present invention consists of a second coil that is at least partially wound around the gas discharge lamp or whose generated magnetic field extends to the gas in the gas discharge lamp, whereby only one terminal of the first coil is galvanically connected to the (high-voltage) transformer and in which also only one connection of the second coil is galvanically connected to the output of the high-voltage transformer. According to a seventh aspect, the technology according to the present invention consists of at least one gas discharge tube further on in the text also referred to as gas discharge lamp. According to an eighth aspect, the technology according to the present invention consists of means for shielding from the environment electromagnetic radiation and / or a magnetic field and / or an electric field produced by the control of the gas discharge lamp. Non-limiting examples of means by which this shielding can be realized are a Faraday cage around the gas discharge lamp and / or the control of the gas discharge lamp consisting of solid metal, perforated metal such as gauze, a so-called hf coating or paint containing 5 metal particles, metal caps or other conductors at the ends of a tubular gas discharge tube and metal wire parallel to the gas discharge tube that acts as a directional antenna for the electromagnetic radiation so that it only propagates in one direction, from the first coil to the second coil.

Now that the basic characteristics of the technology according to the present invention have been explained, a short qualitative description of the technology according to the present invention follows. The microcontroller produces a block voltage on 2 channels in reverse phase which, after amplification in a preamplifier and amplifier, are used to control a (high-voltage) transformer in a push-pull configuration. This creates a high voltage on the secondary side of this transformer. The frequency of this high voltage can be adjusted through software via the microcontroller. By now connecting a connection of the secondary coil of the high voltage transformer to the first coil that is wound around a gas discharge tube and connecting the second connection of the secondary coil of the high voltage transformer to the second coil that is wound around the gas discharge tube, the tube has a varying magnetic field. This causes gas discharge in the tube. The result is that we ignite a gas discharge tube and then let it burn without using electrodes or an incandescent coil. All this is illustrated in figure 1. TR1 is the high voltage transformer. The primary coil of this high-voltage transformer has a center tip B which is connected to the plus of the power supply and 2 connection points A and B which are each operatively connected to the final stage of the push pull amplifier. As is clearly visible in Figure 1, coils L1 and L2 are wound around a gas discharge lamp which in this case is tubular and only 1 connection of coil L1 and coil L2 is galvanically connected to transformer TR1.

Now that the basic elements of the technology according to the present invention have been described and the operation of the technology has also been described qualitatively, a number of preferred embodiments follow.

In a first embodiment, the technology according to the present invention is used to control conventional TL lighting or UVC lamps or tanning lamps. In contrast to the systems on the market, the fixture of the fluorescent lighting 35 comprises a coil L1 and a coil L2 as shown in figure 1. The coils are preferably arranged or cast in 2 hollow holders each with a length of 1 cm up to 50 cm. Each end of the fluorescent tube is slid into a holder. The electrodes of the fluorescent tube and 6 the incandescent coil are not used and are present as dummy. The technology according to the present invention has the advantage over the prior art that it is cheaper and that no TL starter and no choke are required. Furthermore, the technology according to the present invention has the advantage that it does not operate on a supply voltage of 50 Hz but on a higher frequency. Preferably, the frequency of the alternating voltage offered is in the range of 100 Hz to 100 MHz. More preferably, the frequency of the alternating voltage offered is in the range of 1 kHz to 10 MHz. Even more preferably, the frequency of the alternating voltage applied is in the range of 1 kHz to 1 MHz and most preferably the frequency of the alternating voltage offered is in the range of 5 kHz to 100 kHz.

In a second embodiment, the technology according to the present invention is used according to the first embodiment, but in this case the gas discharge tube used has no electrodes and no filament. This means that a completely glass tube or quartz tube or tube with a housing of a composite or other material with a gas therein is used.

In a third embodiment, the gas discharge tube consists of a tube with a gas pressure of 0.001 mbar to 1 bar, preferably with a gas pressure of 0.1 mbar to 100 mbar, even more preferably with a gas pressure of 1 mbar to 50 mbar and most preferably with a gas pressure of 5 mbar to 40 mbar. The tube is filled with conventional gases such as argon and / or neon and / or helium and / or xenon and / or nitrogen and / or mercury and / or metal hydrides and / or hydrogen and / or metal salts including strontium salts. The diameter of the tube is preferably between 1 millimeter and 1 meter, more preferably between 10 millimeter and 10 cm, and most preferably between 10 millimeter and 40 millimeter. The length of the tube is preferably between 1 mm and 5 meters, more preferably between 100 mm and 2 meters and most preferably between 200 mm and 1.5 meters. The number of turns of the induction coils or antenna coils L1 and L2 is preferably between 1 turn and 10,000 turns, more preferably between 10 turns and 1000 turns and most preferably between 50 turns and 50 turns and 500 turns. The length of the coils is preferably between 1 millimeter and 5 meters, more preferably between 10 millimeters and 50 centimeters, and most preferably between 10 millimeters and 100 millimeters.

In a fourth embodiment, the high-voltage transformer in the technology according to the present invention consists of a stack of at least 2 spiral wound coils arranged on a printed circuit board (PCB) to transform the voltage upwards.

It is noted that the primary coil is preferably arranged on a double-sided printed circuit board in which both sides of the printed circuit board are interconnected in such a way that on each side of the printed circuit board exactly the same number of turns and an equal-sized inductance 7 are present. At the location of the interconnection from one side to the other side is the center tip of the primary side of the transformer. By now providing a second coil on a second printed circuit board and placing this second printed circuit board on the first printed circuit board with the primary coil, a push-pull high-voltage transformer is obtained. It is noted that by cleverly placing contact points on each printed circuit board with a coil, coils on different printed circuit boards can be put in series or parallel by stacking. This can be done for both the primary and secondary coils. By arranging thin plastic plates and / or ferrite plates between the printed circuit boards, both the coupling between primary and secondary coil 10 and the insulating capacity of the transformer can be adjusted. The major advantage of a high-voltage transformer built up in this way is a low cost price and a very high breakdown voltage.

In a fifth embodiment, two gas discharge tubes are used which are connected in the manner shown in Figure 2. Figure 2 shows a push-pull high-voltage transformer which operates in analogy with Figure 1. However, this embodiment uses 2 gas discharge tubes g1 and g2. A coil is wound on each of these gas discharge tubes, i.e. coil L1 on g1 and coil L2 on g2. The tubes are preferably positioned relative to each other such that tube g1 and tube g2 are placed parallel to each other such that the end of g2 is below coil L1 and the end of g1 is above coil L2. Furthermore, the distance between g1 and g2 is preferably between 0.01 millimeter and 100 millimeter, more preferably between 0.1 millimeter and 10 millimeter and most preferably between 1 millimeter and 5 millimeter. The consequence of the situation in Figure 2 is that gas discharge occurs in both tube g1 and tube g2. A second consequence is that a corona is created between tube g1 and g2 and ozone is produced with a very high efficiency. It is noted that unlike prior art, ozone electrodes are obtained in this way that do not contain any metal. Tubes g1 and g2 are preferably placed in designated containers which also contain a coil L1 and L2 in the manner as already described in the first embodiment. It is clear to the skilled person that the configuration as shown in figure 2 offers unprecedented possibilities to give the ozone electrodes the desired properties. Thus, the number of turns of coils L1 and L2 can be varied, the thickness of the glass, the type of gas in the discharge tube, the pressure of the gas in the discharge tube and the distance of tubes g1 and g2 with respect to each other. Experiments show that the configuration as shown in Figure 2 leads to very stable ozone electrodes that are much less sensitive to small changes in geometry than electrodes used according to the prior art. Furthermore, it is clear to the person skilled in the art that the placement of the tubes relative to each other represents only one of the many possibilities and that δ configurations of more than 2 tubes are also possible. An ozone generator with a driver as described in the present invention combined with a configuration as shown in Figure 2 is expressly part of the present invention. In a sixth embodiment, the technology of the present invention is combined with a device for wireless energy transfer. The device for the wireless energy transfer here consists of a control as it is also used for a gas discharge lamp, i.e., a microcontroller, preamplifier, amplifier, push-pull transformer. A spiral wound coil L1 is connected to the secondary side of the push pull transformer or a cylindrically wound coil L1 is connected. This coil L1 is inductively coupled to a coil L2 which is also spiral wound or cylindrical wound. All this is schematically shown in Figure 3 for clarification. Coil L1 is connected to coil L3 which is arranged around a gas discharge tube and coil L2 is connected to coil L4 which is arranged around a gas discharge tube. If coil L2 together with the gas discharge tube and coil L3 and L4 are arranged, for example, in a container through which water flows, and coil L1 outside or around the container, a wireless energy supply is obtained for the gas discharge lamp. Coils L1 and L2 as well as coils L3 and L4 can be integrated in the housing if desired.

In a seventh embodiment, wireless energy transfer is realized by applying configuration in Figure 1. To this end, the gas discharge lamp as shown in Figure 1 is placed in a container that is flowed through with air or with water. Coils L1 and L2 are wound around the container or integrated into the container. The result is that the gas discharge lamp in the container is supplied with energy wirelessly. Briefly, this seventh embodiment is a simplification of the sixth embodiment because coils L1 and L2 from Figure 3 can be omitted.

In an eighth embodiment, the wireless energy transfer as described in the sixth or seventh embodiment is used to produce wireless ozone.

This wireless production of ozone preferably takes place with a configuration as described in figure 2.

In a ninth embodiment, the configuration as shown in Figure 2 is used to produce radicals to carry out chemical reactions. To this end, the reactant runs or runs under the influence of gravity as a liquid film along at least one gas discharge lamp. This creates a corona on the liquid surface and the reactant is in contact with ozone in statu nascendi. It is clear to the person skilled in the art that very efficiently polymerization reactions can be carried out in this way as well as the production of epichlorohydrin from glycerol and hydrochloric acid, wherein the glycerol is passed as a liquid film past the gas discharge lamp and wherein the hydrochloric acid is preferably present in gas form 9. It is also clear to those skilled in the art that instead of ozone, UV lamps can also be used to initiate and keep the chemical reactions going.

In a tenth embodiment, one or more of the embodiments one through eight are combined.

In an eleventh embodiment, the technology according to the present invention is applied with technology to disinfect, preferably wirelessly, by means of pulsed electrolysis and / or to disinfect by means of ultrasonic vibrations and / or to disinfect by means of modulated radio waves. It is known to the person skilled in the art that in this way disinfection takes place in a sustainable manner, i.e., more fluid can be disinfected per watt of electrical power than when this power is applied separately with each disinfection technique.

In a twelfth embodiment, in one of the foregoing embodiments, no microprocessor is used as a function generator, but a Colpitts oscillator or a 555 timer or an oscillator with at least one transistor or vacuum tube.

In a thirteenth embodiment, the high-voltage transformer consists of an automobile coil. It is clear to the person skilled in the art that in this case no push-pull circuit but a single-sided control on the primary side of the transformer is used, such as for example a single-ended amplifier.

In a fourteenth embodiment the amplifier consists of a commercially available audio amplifier.

Example 1

A function generator is set to a sinusoidal signal with a frequency of 6 kHz. The function generator is connected to the input of an audio amplifier with a capacity of 1200 watts. The output of the amplifier is connected to a car ignition coil. The high voltage connections of the car ignition coil are connected to a configuration with L1, L2 and a gas discharge tube as shown in figure 1. The gas discharge tube consists of a UVC tube with a power of 18 Watt and a length of approximately 30 centimeters and a diameter of approximately 15 millimeters. A coil L1 and L2 was wound around both ends of the tube, each with 70 turns of insulated copper wire 30 with a diameter of 0.5 mm.

When the function generator and the amplifier were switched on, the UVC tube ignited and remained stably lit. This demonstrates that the operation of the technology according to the present invention can be realized with simple means and works well. It is clear to the skilled person that the configuration from example 1 is far from optimal but nevertheless works well.

Example 2

However, as example 1 in this case, the configuration in Fig. 2 is connected to the high voltage connections of the car coil, that is to say a configuration with 2 gas discharge tubes g1 and g2 which contain a coil L1 and L2, respectively. The gas discharge tubes in this example are 2 tubes, each with a length of 170 millimeters and a diameter of 10 millimeters. These tubes are filled with argon with a pressure at S room temperature of 20 mbar. Coils L1 and L2 each have 120 turns of insulated copper wire with a diameter of 0.5 mm. The tubes are placed according to the arrangement in figure 2 at a mutual distance of 1 millimeter.

Switching on the function generator and the audio amplifier produces a gas discharge in both tubes. A purple glow can also be seen between the tubes and within a few seconds the environment smells of ozone. A sizzling sound is also heard during ozone production.

This demonstrates that the operation of the technology according to the present invention can be realized with simple means and works well. It is clear to the skilled person that the configuration from example 2 is far from optimal but nevertheless works well.

Example 3

As example 2, but now two UVC tubes from example 1 are used instead of the argon tubes, the first UVC tube being provided with a coil L1 and the second UVC tube with a coil L2. Coils L1 and L2 each have 70 turns of insulated copper wire with a diameter of 0.5 mm. According to the configuration in Figure 2, both tubes are laid next to each other at a mutual distance of 1 millimeter.

Switching on the function generator and the audio amplifier causes both tubes to ignite and UVC radiation to be produced. In addition, a purple glow of a corona can be observed between the tubes, a hissing sound is produced and it smells of ozone within a few seconds.

It has thus been demonstrated that the operation of the technology according to the present invention can be realized with simple means and works well. It is clear to the skilled person that the configuration from example 3 is far from optimal but nevertheless works well. Example 4

A PIC processor of the type 16F84A is powered via a 24V laboratory power supply.

For this purpose a voltage-stabilizing element is used which converts the voltage of 24 volts into a voltage of 5 volts. This is achieved by using a voltage regulator of the LM317 type. It is noted that a zener diode can also be used as a cheaper alternative for this application. The software of the PIC processor is set up in such a way that a block voltage is applied to output 1 and output 2 at a frequency of approximately 6 kHz. The preamplifier consists of 2 transistors of the BC547B type, each powered by the PIC processor on the base. The collector of each transistor is connected to the plus via a collector resistor of 470 ohms and the 11 emitter of each transistor is connected to the minus. The pulsed voltage on the collector is taken with a 1 micro Farad header capacitor. The coupling capacitor is then connected to a voltage divider consisting of a series connection of a resistor of 470 ohm and 1 kilo ohm and which is connected to the zero through the resistor of 1 kilo ohm. The voltage across each resistor of 1 kilo Ohm is applied across the gate of a FET of the IRF640 type. The drain of each of these FETs is connected to one end of the primary coil. The center tip of the primary coil is connected to the plus of the power supply. The source of both FETs is connected to zero. The transformer consists of a primary coil with center tip and a secondary coil where the ratio of the number of primary windings: number of secondary windings is equal to 1:50. The transformer is made suitable for frequencies between approximately 5 kHz and 80 kHz with an optimal operation at a frequency around 10 kHz. A tube from example 1 with coils L1 and 12 is connected to the secondary side of the transformer. After switching on the control, the UVC lamp ignites and remains stable.

Example 5

As example 4 but now at a frequency of 10 kHz or at a frequency of 20 kHz or at a frequency of 50 kHz or at a frequency of 100 kHz or at a frequency of 500 kHz or at a frequency of 1 MHz.

Example 6

As example 5, wherein the function generator is a 555 timer or a Colpitts oscillator or another oscillator with at least one transistor or a vacuum tube.

Example 7

As example 5 in which an electromagnetic transmitter is used as a function generator and amplifier and in which coils L1 and L2 with 1 wire according to figure 1 are connected to the final stage of the electromagnetic transmitter and wherein the electromagnetic transmitter operates in the range of 1 MHz to 150 MHz .

Example 8

As example 4 in which not a push pull amplifier but a single ended amplifier 30 is used to drive the high voltage transformer.

Now that the technology according to the present invention is completely clear and has been illustrated with a number of examples, a summary follows of embodiments of wireless energy transmission that can be used in combination with the technology in this application.

Such combinations are expressly covered by the technology of the present invention, in particular the use of tuned circuits to increase the energy efficiency of the transfer of electrical energy.

12

Description of wireless energy transfer applications in combination with the technology according to the present invention

The technology according to the present invention uses energy transfer through induction. This principle known in electrical engineering is generally applied by using at least 2 cylindrically wound coils. The first coil is connected to a transmitting device which preferably supplies sinusoidal alternating voltage. The second coil is placed in the field of the first coil. An alternating voltage is created in the second coil due to induction. If a load, such as a lamp, is connected to the 2nd coil, it can be supplied with energy. The above implies that it is technically possible to build in a first coil in a wall or a container or another closed space and to connect this coil to a sine generator that is optionally also built into the wall. If we subsequently hang a painting with a suitable coil and lighting on the wall in the vicinity of the first coil, then the transmitter device in the wall can wirelessly supply the lighting of the painting with energy. This makes it possible to commission and exchange objects that use electricity without suspicious electricity wires and without the intervention of a professional. In this context, lighting is also understood to mean gas discharge lamps, including lamps for the production of ozone according to the technology of the present invention and UVC lamps and tanning lamps.

It is clear to a person skilled in the art that the efficiency with which energy can be transmitted through induction greatly decreases with increasing distance between the transmitting coil and the receiving coil. It is also clear to the person skilled in the art that for transferring a significant amount of energy, coils with a relatively large diameter and a relatively large number of turns are necessary. Cylindrically wound coils, if used in the present invention, would quickly have unacceptably large dimensions. A large diameter of the coil is generally acceptable, but in particular the length of the cylindrical coil is quickly so large that it is no longer technically and / or economically feasible to install such a coil in the wall or in a light box. Moreover, in the case of a light box, it is desirable for aesthetic reasons to make the light box 30 as flat as possible.

The inventors of the present invention have determined that coil wound coils are extremely suitable transmit coils and receive coils for making flat transmitting devices and receiving devices according to the concept of the present invention. In a fifteenth preferred embodiment, the transmit and receive coils are etched on a printed circuit board 35. In a sixteenth preferred embodiment, a coil is etched on each side of a double-sided printed circuit board, the first coil being connected to a sine generator and the voltage supplied by the sine generator being transformed by coupling the first coil to the second coil. This allows the range of the transmitting device to be increased. In the receiving device, the voltage is optionally analogously transformed down to match the impedance of the lighting to the impedance of the receiving coil. In a seventeenth preferred embodiment, the alternating voltage is rectified by means of a diode or diode bridge and, if desired, smoothed with one or more capacitors. The DC voltage thus obtained is used to charge a battery in the receiving device. In an eighteenth preferred embodiment, the alternating voltage in the receiving device is used to energize and illuminate EL foil. In a nineteenth preferred embodiment, the spiral wound coil of the receiving device is applied to a foil by means of a conductive coating. In a twentieth preferred embodiment, the coil wound coil is applied to the back of the receiving device in general and EL foil in particular and connected, whereafter the EL foil is subsequently laminated again so that the coil is fully insulated. In a twenty-first preferred embodiment, the coil wound coil is printed on the receiving device in general and EL foil in particular, and insulation with a coating takes place. In a twenty-second preferred embodiment, the coil of the transmitting device is connected in series and / or connected in parallel with a capacitor to make a resonant circuit in this way. Optionally, the coil of the receiving device is also equipped with a series-connected and / or a parallel-connected capacitor in order to obtain a tuned circuit also in the receiving device. The characteristics of the coils and capacitor (s) are tuned to the applied frequency of the alternating voltage in the final stage of the transmitting device. It is clear to the skilled person that the method and device with a resonance circuit has the advantage that the induction voltages in the coils become higher. In this way it can be achieved that the energy transfer can be carried out over a greater distance between coils of the transmitting device and the receiving device, respectively. In a twenty-third preferred embodiment, the present invention is used to illuminate microscope object glasses. By applying EL foil to the underside of a specimen slide, an specimen slide can be provided with an adjustable amount of light according to one of the previous preferred embodiments, but not limited thereto. The advantage here is that the transmitting device can be built into the microscope and that the slides can be used independently of the transmitting device and can easily be replaced. In a twenty-fourth preferred embodiment, a flat coil is mounted on a microscope slide and this coil is energized by another coil or by connecting the coil to the slide on a transmitting device. The result is that micro-organisms that are present on the slide are exposed to an alternating magnetic and / or electric field. In this way the behavior of micro-organisms under the influence of (radio) waves can be studied or changed without electrodes having to be brought into direct contact with the liquid on the slide. Use is preferably made of resonant circuits in the transmitting or receiving device to promote energy transfer. In a twenty-fifth preferred embodiment, in the transmitting device use is made of a sinusoidal alternating voltage with a frequency in the range of 1 Hz to 1 kHz and / or a frequency in the range of 1 kHz to 5 kHz and / or a frequency in the range of 5 kHz to 10 kHz 10 and / or a frequency in the range of 10 kHz to 100 kHz and / or a frequency in the range of 100 kHz to 1 MHz and / or a frequency in the range of 1 MHz to 100 MHz and / or a frequency in the range of 100 MHz to 100 GHz. It is clear to the person skilled in the art that depending on the power to be transferred, the impedance of the load in the receiving device, the distance to be bridged for wireless energy transfer, the maximum applicable diameter of the coils, one of the above-mentioned frequency ranges is preferred. Furthermore, it is clear to a person skilled in the art that, under certain circumstances, a pulse-shaped alternating voltage, a pulse-shaped direct voltage or a block voltage are preferable to a sinusoidal alternating voltage.

In order to achieve efficient energy transfer with coils having a limited number of windings, a wireless energy transmission transmitter device is preferably designed to be / set to a transmission frequency above 1 kHz, even more preferably to a transmission frequency above 5 kHz and most preferably at a transmission frequency above 10 kHz. The primary circuit of the receiving device generates an alternating voltage with the same frequency as that of the transmitting device. This does not cause any problems for controlling an LED lighting, but many commercially available EL lighting must be controlled with an alternating voltage of approximately 200 Hz to 2 kHz. In order to make an alternating voltage with a frequency higher than approximately 2 kHz suitable as an energy source for an EL lighting, the receiving device is equipped with a diode (bridge) and a smoothing capacitor to rectify the alternating voltage in this way. The DC voltage thus obtained is used as a power source for a frequency generator which turns the DC voltage into an alternating voltage with the desired frequency in the range of 200 Hz to 2 kHz. The EL lighting is then connected to this alternating voltage. Commercially available miniature voltage inverters for EL lighting such as type 1V504 (WAEL, MBLR6M03) are extremely suitable for use in combination with the present invention. If desired, information transfer can also be applied in addition to energy transfer.

15

It is clear to the person skilled in the art that this information transfer preferably takes place at high frequencies so that a large transfer speed of information can be realized. A method of realizing information transfer and energy transfer simultaneously is by amplitude modulation, frequency modulation, phase modulation or single-sideband modulation of a carrier wave.

Example 9

The arrangement from example 4 is operated at a frequency of 40 kHz. The transformer used is a transformer with center tip on the primary side of the coil and a winding ratio primary: secondary of 1: 2. Electroluminescent film is connected to the secondary winding of the output transformer.

Switching on the electronic circuit causes the electroluminescent film to light up.

Example 10

As example 9 but now a flat spiral wound coil is connected to the secondary winding of the transformer with center tip. Electroluminescent film is connected to a second coil wound coil.

Switching on the circuit leads to the foil lighting up.

1038724

Claims (7)

Device for producing ozone and / or radicals characterized by • a power supply that produces a direct voltage • a microprocessor according to the definition in this application that produces a pulsed direct voltage whose frequency can be adjusted by software • a pre-amplifier that has at least one transistor or includes a FET or a vacuum tube • a power amplifier that contains at least one power transistor or a FET 10 or a vacuum tube • a transformer that contains at least a primary and a secondary coil • at least a first gas discharge lamp with or otherwise operatively connected to the first gas discharge lamp • first coil of which the generated magnetic field extends to the gas in the gas discharge lamp • at least one galvanic connection between the first coil and a first connection to the secondary coil of the transformer • at least one second gas discharge lamp with da second coil wound or otherwise connected to the second gas discharge lamp and whose generated magnetic field extends to the gas in the gas discharge lamp • at least one galvanic connection between the second coil and a second connection to the secondary coil of the transformer • at least a first coil air gap between at least a first gas discharge lamp and a second gas discharge lamp in which at least one corona is formed in the first air gap with formation of ozone and / or radicals Device as claimed in claim 1, wherein the gas pressure in the gas discharge lamps is greater than 1 millibar and less than 200 millibar. Device as claimed in any of the foregoing claims 1 and 2, wherein the gas in the gas discharge lamps is a noble gas or a mixture of noble gases. Device as claimed in any of the foregoing claims 1 to 3, plus means for flowing a first liquid film along the glass surface of at least a first gas discharge tube, with the result that this first liquid film 35 is in contact with the corona and consequently chemical reactions in this liquid film. 1038724 A chemical reactor according to claim 4. A chemical reactor according to claim 4 for the production of epichlorohydrin from glycerol and hydrochloric acid. 7. Method for the production of ozone or radicals characterized by the use of a device according to one of the preceding claims 1 to 6. 1 03 8 72 4