NL1036561C2 - METHOD AND DEVICE FOR TREATING AND / OR CHARACTERIZING A FLUID. - Google Patents

Description

Method and device for treating and / or characterizing a fluid

The present invention relates to a method and device for treating and / or characterizing a fluid characterized by a container in which there is at least one gas, means for adding energy to the gas creating a plasma and means for controlling the radiation that the plasma transmits to a fluid in which the gas preferably consists of hydrogen with a pressure below 0.1 bar, the means for adding energy to the gas preferably of an incandescent spiral and / or a low-frequency alternating voltage and / or a high-frequency alternating voltage and / or a direct voltage and / or a pulsed direct voltage and / or inorganic salts including potassium salts and strontium salts and the device for transferring the radiation produced by the plasma preferably consists of a quartz tube through which the fluid flows.

Introduction 15 There is a growing need for sustainable purification and disinfection technology in the chemical industry, the process industry, the food industry and the process technology water world. The present invention describes such a technology.

It is known in the literature that a plasma can be formed in a vacuum tube 20 containing hydrogen gas at a pressure of 1 millibar. In a known embodiment there is a mesh in the vacuum tube on which a layer of a potassium compound is applied and wherein this gas is folded in a cylindrical form around a tungsten heating coil. By electrically heating the heating coil to a temperature of approximately 1100 degrees Celsius and plasma. This is special because, according to current theory, no plasma formation is expected under these conditions. It is also known in the open literature that the plasma produces radiation in the ultraviolet region and that the wavelength of this ultraviolet light is very short under certain conditions, i.e., shorter than 100 nm.

The present invention describes a method and device with which it is possible to produce high doses of short wave UV radiation and to transfer it to a fluid such that disinfection and / or chemical reaction occurs in the fluid.

Technical description of the present invention

In a conventional gas discharge lamp such as a fluorescent tube, gas discharge takes place between 2 electrodes which are placed on either side of the tube. In commercially available gas discharge lamps, depending on the application, there is a noble gas (mixture) or mercury vapor. According to the state of the art, the electrodes of the gas discharge lamp 2 are designed as a filament and are preferably covered with a paste of barium oxide. The barium oxide enables electron emission at moderately high temperatures. A large voltage difference between the electrodes is required for the formation of the plasma. This voltage difference is applied by means of induction. In practice, it appears that a voltage difference between the electrodes of approximately 1000 volts is sufficient to cause a plasma to form in the lamp. Since the conductivity of the plasma is very high, the voltage difference between the electrodes that is necessary to maintain the plasma is low. The plasma is known to emit UV radiation. In particular gas discharge lamps with mercury vapor appear to be extremely suitable for generating UV radiation for disinfection purposes.

The present invention relates to the use of gas discharge lamps containing preferably hydrogen gas under very low pressure, preferably in the range of 0.01 mbar to 0.1 bar for the treatment of a fluid including disinfection. In this application fluid is understood to mean: a gas (mixture) and / or a liquid (mixture) and / or a mist of liquid in a gas and / or a dispersion of gas in a liquid.

In a first embodiment, the gas discharge tube is made of quartz and equipped with a mesh on which a layer of a potassium compound is applied and wherein this gas is folded in cylindrical form around a tungsten heating coil. By electrically heating the heating coil to a temperature of approximately 1100 degrees Celsius 20, plasma is created. This plasma emits ultraviolet light in the range of approximately 50 nm to approximately 350 nm. The intensity of the ultraviolet light and the wavelength distribution can be adjusted based on the temperature of the glow filament and the amount of potassium and / or strontium salt applied to the mesh. A fluid flows around the quartz tube. As a result, the fluid is exposed to the ultraviolet radiation and disinfection takes place. It is noted that the energy efficiency of the system according to the present invention, with which UV light is produced and a fluid can be disinfected, is much higher than prior art systems.

In a second embodiment, the gas discharge tube of the first embodiment is provided with electrodes which can be connected to an alternating voltage and / or a direct voltage and / or a pulsed direct voltage and / or an electromagnetic transmitter. It is clear to the skilled person that in this way the amount of energy dissipated in the plasma can be accurately adjusted. The inventors of the present invention have established that in this way the intensity of the UV radiation and the energy efficiency with which useful UV radiation is generated can be adjusted. In a third embodiment, the electrodes from the second embodiment are equipped with glow spirals that contain a layer of an inorganic salt. A non-limiting list of suitable inorganic salts is mercury salts, potassium salts, strontium salts, barium salts, compounds containing metal ions, carbonates, silicates. It is noted that when this embodiment is used the incandescent spiral as described in the first embodiment can be omitted if desired.

In a fourth embodiment, energy is transferred to the gas in the gas discharge lamp by means of induction. This is possible by using coils or ferrite rods around which a coil is wound placed in or in the vicinity of the gas discharge lamp. These coils can be directly supplied with energy by connecting them to a (high-frequency) alternating voltage source or indirectly by induction.

In a fifth embodiment, a preferably fluidized bed of induction coils is located in the fluid in the vicinity of particles in which hydrogen is under low pressure. The individual particles are supplied with energy by means of induction, as a result of which gas discharge takes place in the particles and the particles start to emit UV light, resulting in water treatment including disinfection.

In a sixth embodiment the gas in one of the preferred embodiments one to five consists of a mixture of hydrogen and / or helium and / or argon and / or krypton and / or neon and / or nitrogen and / or oxygen and / or a halogen and / or a metal vapor.

It is clear to those skilled in the art that the embodiments listed can be combined and that there are various ways of efficiently passing a fluid past the gas discharge lamp. The embodiments are therefore by no means limitative examples for the present invention.

It is also clear to the person skilled in the art that instead of quartz, as a material for transporting UV radiation from a space in which the UV radiation is generated to another space in which a fluid is present, other materials which are permeable to UV radiation can also be made. applied.

Furthermore, it is clear to the person skilled in the art that the technology according to the present invention offers unprecedented possibilities as a sensor, i.e. for determining the properties of a fluid, since in particular UV radiation with a short wavelength is absorbed by many different types of fluid and chemical compounds. As non-limiting examples for a sensor based on the technology according to the present invention 30 are mentioned: • A sensor for fingerprinting water in which, depending on the components dissolved in the water, UV radiation of a certain wavelength is absorbed. In short, this means that conventional UV spectroscopy can be extended with a technology according to the present invention to a range with shorter wavelengths.

• A sensor for fingerprinting water, whereby adsorption of components present in the water on a surface that is permeable to 4 UV radiation is preferably achieved electrically and / or chemically. As a result, these components are concentrated in the water and the sensitivity of the short-wave UV spectroscopy is increased. The adsorption layer for the components present in the water is preferably provided on the outside of the container 5 in which the short-wave UV radiation is generated.

• A sensor for fingerprinting water in which a surface of the sensor is coated with a compound that converts UV radiation into radiation with a broad spectrum of different wavelengths and after which spectroscopy with a large bandwidth is applied.

In addition, it is clear to the person skilled in the art that the application of coatings on the outside of the container in which the short-wave UV light is produced enables the following applications on a production scale: • Selective adsorption and efficient decomposition of traces of contaminants in a fluid including water.

· Conversion of UV radiation into a broad spectrum of radiation from the short-wave UV

area to the infrared area. By changing the nature of the coating it is possible to use the radiation thus generated with a high efficiency for, for example, the cultivation of algae, chemical conversions including oxidation reactions, disinfection but not limited to that.

Finally, it is clear to the person skilled in the art that the technology according to the present invention can be combined with more common technologies such as the addition of hydrogen peroxide and ferrous (Fe (11)) ions, ultrasonic technology, chemical oxidizing agents including ozone and active chlorine. In this way a synergistic effect is obtained which means that water can be treated at lower costs and with a higher efficiency than if each of these techniques were applied separately.

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Claims (1)

Method or device as described in the text. 10 15 20 25 30 35 1036561