RU178262U1 - Gas treatment plant and gas discharge filter - Google Patents

Abstract

The utility model relates to gas purification devices and is intended for purification of atmospheric (external) and recirculation air in the supply and exhaust ventilation and air conditioning systems in public buildings and industrial structures. The gas purification installation contains sequentially located and interconnected purification units, the latter are formed by an electrostatic filter and a gas discharge filter, the filters being directly communicated with each other or installed in a single or prefabricated housing in the following sequence along the gas being cleaned: electrostatic filter, followed by a gas discharge filter. The gas discharge filter of the gas treatment plant contains mesh metal electrodes with spikes located on them and metal electrodes located in the glass, installed inside the housing and connected to a power supply unit with an output voltage of 5000-30000 V and a frequency of 50-9000 Hz, while mesh metal electrodes made flat and arranged parallel to each other, and the metal electrodes located in the glass are located between the mesh metal electrodes parallel to the last, while located in Tekle metal electrodes are made from a flat metal sheet, sandwiched between two layers of glass, and on the perimeter of the metal sheet adjacent to the edge of the metal sheet layers are melted glass to form a glass front wall. As a result, a simplification of the design is achieved by eliminating bypass elements (hoses) between the cleaning units and compartments in which the gas discharge filter is installed, the electrodes are made in the form of flat elements, and the metal electrode located in the glass is constructed in the form of a structurally and technologically simple element - a flat metal sheet.

Description

The utility model relates to gas purification devices and is intended for purification of atmospheric (external) and recirculation air in the supply and exhaust ventilation and air conditioning systems in public buildings and industrial structures.

A known installation for gas purification, in particular a water separator containing a high voltage source and sequentially located flow equalization chamber with aerodynamic elements, a charging chamber with corona needle and non-corona mesh electrodes and a mixing chamber (see, copyright certificate SU No. 1005916, class B03C 3 / 12, 03/23/1983).

From the same copyright certificate, a charging chamber (essentially a gas discharge filter) containing corona-shaped needle and non-corona mesh electrodes is known.

The known installation and the charging chamber installed in it allows the gases to be cleaned only of dust and droplets of water and oil that are in an aerosol state, which narrows the capabilities of this installation and makes its use unpromising.

Closest to the utility model in terms of technical nature and the achieved result is a gas purification plant comprising an inlet and outlet nozzles, a preliminary purification unit, a gas discharge unit and a final purification unit sequentially located between them, while it is provided with two arms, the preliminary purification unit, the gas discharge unit and the final cleaning unit are made in the form of separate blocks and are interconnected by sleeves (see utility model certificate RU No. 40013, class B03C 3/02, 08/27/2004).

From the same certificate for a utility model, a gas-discharge unit of a gas treatment plant is known, comprising a housing, inside of which there is at least one compartment with electrodes located in each of them, forming discharge pairs, as well as a power source, one of the electrodes of each of the discharge pairs placed inside the glass layer, and a power supply with a voltage at the output of 5000-20000 V and with a frequency of 50-9000 Hz was used as a power source.

This unit and its gas discharge unit provide for the purification of gases - air emissions of food, industrial and other enterprises from harmful and foul-smelling gaseous substances and vapors. However, the presence of sleeves between the cleaning nodes, as well as the installation of compartments with electrodes in the housing, allowing more flexible configuration changes to the installation leads to excessive hydrodynamic losses.

The problem, which the utility model is aimed at, is to reduce hydrodynamic losses.

The technical result consists in simplifying the design by eliminating bypass elements (hoses) between the cleaning units and compartments in which the gas discharge filter is installed, the electrodes are made in the form of flat elements and the metal electrode located in the glass is constructed in the form of a structurally and technologically simple element - a flat metal sheet.

The problem is solved, and the technical result is achieved due to the fact that the installation for gas purification contains sequentially located and interconnected cleaning units, the latter are formed by an electrostatic filter and a gas discharge filter, the filters being directly communicated with each other or installed in a single or prefabricated housing in the following sequences along the cleaned gas: electrostatic filter, followed by a gas discharge filter.

The gas discharge filter at the outlet can be equipped with a catalytic filter for cleaning the gas to be cleaned from ozone.

A hydraulic filter can be installed in front of the electrostatic filter.

In addition, the task is solved, and the technical result is achieved due to the fact that the gas-discharge filter of the gas treatment plant contains installed inside the housing and connected to the power supply with an output voltage of 5000-30000 V and a frequency of 50-9000 Hz with metal mesh electrodes with spikes located on them and metal electrodes located in the glass, while the mesh metal electrodes are made flat and parallel to each other, and the metal electrodes located in the glass are located s mesh between the metal electrodes parallel to the latter, wherein disposed in the glass, metal electrodes are made from a flat metal sheet which is placed between two layers of glass, and on the perimeter of the metal sheet adjacent to the edge of the metal sheet layers are melted glass to form a glass front wall.

The spikes on the mesh metal electrodes are preferably staggered in parallel rows on both sides and are inclined to the flat surface of the mesh metal electrode at an angle of 87 ° to 88 °.

The metal electrodes located in the glass are preferably made of copper or brass, and quartz glass is used as the glass.

At the outlet, the gas discharge filter of the installation can be equipped with a catalytic filter to purify the ozone to be cleaned from gas.

Mesh metal electrodes and metal electrodes located in the glass can be made in the form of separate functionally independent cells, which can be installed in the installation casing in parallel and / or sequentially along the gas being cleaned.

The drawing schematically shows a longitudinal section of a gas treatment plant and a gas discharge filter as part of this installation.

The gas purification installation contains sequentially located and interconnected purification units, which are formed by an electrostatic filter 1 and a gas discharge filter 2 and, moreover, the filters are directly communicated with each other or installed in a single or prefabricated housing 3 in the following sequence along the gas being cleaned: electrostatic filter 1 and gas discharge filter 2.

The gas discharge filter 2 at the outlet can be equipped with a catalytic filter 4 for cleaning the gas to be purified from ozone.

In front of the electrostatic filter 1, a hydraulic filter 5 can be installed.

The gas discharge filter 2 of the gas treatment plant contains installed inside the casing 4 and connected to the power supply 6 with a voltage at the output of 5000-30000 V and with a frequency of 50-9000 Hz, mesh metal electrodes 7 with spikes 8 located on them and metal electrodes 9 located in the glass The mesh metal electrodes 7 are made flat and arranged parallel to each other, and the metal electrodes 9 located in the glass are located between the mesh metal electrodes 7 parallel to the last. The metal electrodes 9 located in the glass are made of a flat metal sheet placed between two glass layers 10, and along the perimeter of the metal sheet, the glass layers 10 adjacent to the edge of the metal sheet are fused to form an end glass wall.

The spikes 8 on the mesh metal electrodes 7 are preferably staggered in parallel rows on both sides and are inclined to the flat surface of the mesh metal electrode 7 at an angle of 87 ° to 88 °, which allows the studs to be evenly distributed over the surface and in combination with the above the angle of the spikes to ensure effective gas purification, due to its processing throughout the entire volume of the gas discharge filter 2 in the installation area of the mesh metal electrodes 7.

The metal electrodes 9 located in the glass are preferably made of copper or brass, and quartz glass is used as the glass.

At the output, the gas discharge filter 2 of the installation can be equipped with a catalytic filter 4 for cleaning the gas to be purified from ozone.

Mesh metal electrodes 7 and metal electrodes 9 located in the glass can be made in the form of separate functionally independent cells, which can be installed in the housing 3 of the installation in parallel and / or sequentially along the gas being cleaned.

When a gas treatment plant is in operation, the latter pass sequentially through an electrostatic filter 1 and a gas discharge filter 2. The electrostatic filter 1, due to ionization of the gas to be purified and subsequent deposition of ionized particles, provides gas and smoke purification from aerosols. The electrostatic filter 1 includes a high-voltage source of direct current 11, an ionizer 12 of the gas to be cleaned, located at the inlet, and a particle precipitator placed behind it 13. The cleaning process in them is carried out due to the electromagnetic field created by the high-voltage source of direct current 11 (up to 30 kV). When a current is supplied from a constant electric current source to the electrodes of the ionizer 12 between the electrodes, an electrostatic field causes a corona gas discharge to occur. Particles contained in the gas being cleaned, passing through the corona discharge zone — the ionization zone of the gas being purified, acquire a positive electric potential and then are deposited on the electrodes of the precipitator 13.

If necessary, the electrostatic filter 1 may consist of several stages and may contain several parallel and / or sequentially installed discharge filters 1.

Next, the gas to be cleaned enters the gas discharge filter 2, the principle of which is based on the effect of the barrier-streamer discharge (cold plasma) on the gas to be cleaned, for example, the air being cleaned and supplied to the room. A plasma discharge is created between the mesh metal electrodes 7 located between the glass layers 10 of the glass metal electrodes 9, which are supplied with alternating voltage from a high voltage transformer (up to 30 kV). The electrodes can be located in the housing 3 in the form of separate cells arranged in parallel and / or in series. The gas discharge filter 2, due to the oxidation of substances in the gas being cleaned, cleans it of harmful and odorous substances. However, this leads to the formation of ozone in the gas to be cleaned, in particular in the air to be purified, from which, if necessary, it is carried out using a catalytic filter 4.

In the case of the presence of a large amount of relatively large particles (e.g. dust) in the gas to be cleaned, as well as if necessary, to cool and moisten the supplied gas to be cleaned, an hydraulic filter 5 is installed in front of the electrostatic filter, which can also extinguish sparks and other burning particles in addition to cooling the hot gas to be purified. The principle of operation of a hydraulic filter is based on spraying finely dispersed water in an air stream. Water in this block is continuously circulating from the nozzles 14 through the gas stream and enters the pan 15, from where it again goes to the nozzles 14.

This utility model can be easily manufactured using easily accessible metal and dielectric materials and can be widely used for cleaning air or gas from dust, smoke and other impurities in both residential and industrial premises.

Claims (8)

1. Installation for gas purification, containing sequentially located and connected to each other cleaning units, characterized in that the cleaning units are formed by an electrostatic filter and a gas discharge filter, the filters being directly communicated with each other or installed in a single or prefabricated housing in the following sequence along the path of the gas to be cleaned : electrostatic filter, followed by a gas discharge filter. 2. Installation according to claim 1, characterized in that the gas discharge filter at the outlet is equipped with a catalytic filter for cleaning the gas to be purified from ozone. 3. Installation according to claim 1, characterized in that a hydraulic filter is installed in front of the electrostatic filter. 4. A gas discharge filter of a gas treatment plant, comprising metal mesh electrodes installed inside the housing and connected to a power supply unit with a frequency of 50-9000 Hz with spikes located on them and metal electrodes located in the glass, characterized in that the power supply unit is configured with an output voltage 5000-30000 V, the metal mesh electrodes are flat and parallel to each other, and the metal electrodes located in the glass are parallel between the metal mesh electrodes about the latter, while the spikes on the mesh metal electrodes are arranged in parallel staggered rows, the metal electrodes located in the glass are made of a flat metal sheet placed between two layers of glass, and the glass layers adjacent to the edge of the metal sheet are melted to form an end face glass wall. 5. The gas discharge filter according to claim 1, characterized in that the spikes on the mesh metal electrodes are located on both sides and are inclined to the flat surface of the mesh metal electrode at an angle of 87 ° to 88 °. 6. The gas discharge filter according to claim 1, characterized in that the metal electrodes located in the glass are made of copper or brass, and quartz glass is used as glass. 7. The gas discharge filter according to claim 1, characterized in that at the outlet it is equipped with a catalytic filter for cleaning the gas to be purified from ozone. 8. The gas-discharge filter according to claim 1, characterized in that the mesh metal electrodes and metal electrodes located in the glass are made in the form of separate functionally independent cells that can be installed in the installation casing in parallel and / or sequentially along the gas being cleaned.

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