DE2264036C3 - Electrostatic particle separator for gases - Google Patents

Description

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The invention relates to an electrostatic particle separator for gases of the type specified in the preamble of claim 1, as from US-PS 49 667 known.

Such a device is used, for. B. to separate the contaminating particles contained in the atmospheric air from a sample of this air or to defoliate and thus purify a gas. As a result of this separation of the impurities contained in the atmosphere or another gas, these can be analyzed qualitatively and quantitatively at the same time, that is to say the content of impurities can be determined and a chemical analysis thereof can be carried out.

The monitoring of air pollution especially in the area of large cities, industrial centers, etc. represents a very important task, so that already numerous types of devices for such Samples are known of which should be mentioned:

Filtration systems that work with filter cloths. In such systems, the pores of the Filter cloths very quickly so that the device becomes ineffective;

Systems for separation by mass inertia that work with settling, impact or centrifugal forces. Such systems have the disadvantage that they are used for the separation of particles of low mass, e.g. B. Particles less than a micron in diameter, are ineffective;

Systems that work with thermal precipitation (photon bombardment) and in contrast to the aforementioned allow only low mass particles to be separated;

Electrostatic deposition devices generally consisting of a tip or wire as Corona (ionization) electrode, which is arranged in the axis of a straight cylinder, on which If the particles were to be deposited (US Pat. No. 3,449,667). The recovery of the thus obtained Deposition is difficult and the performance of such devices decreases with the formation of deposits of the particles on the wire decrease very rapidly over time. In addition, such devices can in principle not set up to automatically measure the particle content of a gas. Let these difficulties also not remedied by dividing the gas flow after flowing through the corona discharge field, as known from DT-PS 3 14 171

The invention is intended to provide a device for the electrostatic separation of in a gas contained particles are created, which the disadvantages of the known methods indicated above and devices and avoids quantitative particle separation and analysis and continuous Measurement of the particle content enables the ionization electrode to be practically free of deposits remains.

This object is achieved by an electrostatic particle separator of the type specified at the beginning Kind, which according to the invention has the features specified in the characterizing part of claim 1.

Preferred embodiments result from the Subclaims. With the separator according to the invention, the contaminated test gas contained particles are charged and deposited at the same time. The charging of the particles becomes achieved by the gas molecules that are generated by the application of a potential difference between the electrodes occurring corona discharge are ionized.

The particles ionized in this way pass under the action of between the plate electrode and the Corona effect delivering ionization electrode applied electrostatic field to the plate electrode and

are caught by this. Vortex formation due to the electric wind is eliminated by a stream of clean gas between the electrodes, causing the loss of aerosols to the Chamber walls is avoided. This result is obtained by the under very favorable conditions Ionization electrode in the axis of the clean gas feed line or at the boundary between the clean gas feed line and the test gas feed line is arranged in the clean gas flow.

The invention is illustrated by the following description of a given by way of example only Embodiment. The description relates to the figure that shows this invention in longitudinal section shows electrostatic precipitator

The electrostatic precipitator shown in the figure has essentially an elongated sealed chamber 2 of, for example, a prismatic shape, which is connected at one of its ends to the gas supply lines 4 and 6 and at the other end to the gas discharge line 8 A conductive metal plate 10 fastened to its inner wall and electrically insulated from it. Furthermore, a wire electrode 12, which is arranged parallel to its axis and in the extension of the supply line 6 and is held by two insulators 14 and 14 ', is arranged in the chamber. A constant or optionally modulated direct voltage potential Vi can be applied between the wire electrode 12 and the plate electrode 10 by means of a direct current generator 16. In this embodiment, the gas discharge line 8 mV is connected to a suction device 17 of known type. In the interior of the chamber 2, the gas flows corresponding to the supply lines 4 and 6 are partially separated by the guide bodies 18 and 18 '. The chamber 2 here has a line 20 arranged in the extension of the supply line 6. In a modification, the line 20 can be closed by a controllable valve 22.

In the figure, a dust collector is shown in which the electrical conductor connected to the conductive plate Corona effect creates a wire electrode 12 parallel to the axis of the chamber 2, but the can electrical conductors, as indicated above, also from a conductive tip perpendicular to the conductive plate 10 exist.

The method of operation of the device results directly from the preceding description. The contaminated gas to be examined entering through the examination gas line 4 into the chamber 2 ionized by the interaction of wire electrode 12 and plate electrode 10. The wire electrode 12 behaves like a charge-releasing element, since when a potential difference V is applied between it, it and the plate electrode 10 is subjected to the action of corona. So the gas is ionized and the Ionic space charge ensures that the particles suspended in the gas are charged. These charged particles are then attracted to the plate electrode 10, which behaves like a collector plate and so the im

Contaminated gas contained particles catches The gas supplied through the clean gas supply line 6 can be either a "pure" gas or the gas derived from the discharge line 8 and compensates for the Corona discharge generated electric wind. So there is the formation of eddies and thus the separation of particles on the walls of the chamber 2 outside the plate electrode 10 avoided. The through the The amount of gas supplied to the clean gas feed line 6 can advantageously be 5 to 30% of the throughput of contaminated Gas.

For example, the flow rate of the gas in the chamber 2 under the action of Suction device 17 advantageously between 10 and 400 cm / sec, the direct current potential difference Vi between of the plate electrode 10 and the wire electrode 12 between 2 and 20 kV and in a preferred one Embodiment the length of the chamber 2 depending on the applied voltage, the flow rate of the gas and its content of impurities are between 3 and 30 cm.

In order to automatically measure the content of dust particles in the polluted gas, the Collecting electrode 10 an automatic measuring device can be connected, which consists of an electrometer, a piezoelectric sheet or a moving film, while the amount of the in the Device introduced contaminated gas is measured by means of a flow meter.

If a gas is to be dedusted, a device for cleaning the plate electrode 10 be provided for example by wiping or rinsing.

Investigations carried out with such a device on contaminated and opaque smoke gas showed that the polluted air came out completely transparent. All in her Particles contained therein were deposited on the plate electrode 10 only.

Other studies on a gas contaminated with latex spheres 0.1 microns in diameter showed that 90% of these particles had an average contaminant gas transit time were collected by the plate electrode 10 by the deposition chamber for 0.05 seconds and that at 0.8 micron particles the deposition (performance) was over 99%.

The dust separator according to the invention thus shows the same in comparison with known devices Type has numerous advantages. It is very simply set up and therefore cheap and easy to maintain and very operationally reliable. Since the particles are collected on a single flat plate, they can be used for a chemical analysis can be taken off very easily.

The invention is of course not limited to the im individual described and illustrated example is limited, but also includes modifications. Especially the plate IC can replace at least a part of the inner wall of the chamber 2.

1 sheet of drawings

Claims (8)

Patent claims: 1. Electrostatic particle separator for gases, which has an elongated sealed chamber, on the a gas inlet opens at one end and a gas outlet is provided at the other end, wherein inside the chamber at least two interacting, fulfilling different tasks Electrodes are provided, one of which is arranged in the vicinity of the chamber wall and the other geometriscfi as an ionization electrode is formed, and the electrodes with a DC generator are connected, which maintains a potential difference between them, thereby characterized in that a clean gas feed line is parallel to the test gas feed line (4) (6) opens into the chamber (2) that flow guide elements at the gas inlet and at the gas outlet (18, 18 ') are provided, soft the entering through the test gas supply line and through the gas discharge line (8) exiting stream of contaminated gas is relatively independent keep the ionization electrode from the clean gas stream entering through the clean gas supply line (12) is arranged in the clean gas flow and the electrode arranged in the vicinity of the chamber wall is a Plate electrode arranged in the vicinity of the gas supply line and gas discharge line (10), and that the direct current generator (16) optionally with a device for modulating the potential difference is equipped 2. Particle separator according to claim 1, characterized in that the ionization electrode (12) is arranged in the extension of the clean gas supply line (6) 3. Particle separator according to claim 1 or 2, characterized in that the ionization electrode (12) is a lead wire substantially parallel to the plate electrode (10). 4. Particle separator according to claim 1 or 2, characterized in that the ionization electrode (12) is a conductor tip perpendicular to the plate electrode (10). 5. Particle separator according to one of claims I to 4, characterized in that the gas discharge (8) is equipped with a suction device (17). 6. Particle separator according to one of claims 1 to 5, characterized by one opposite the Line (20) arranged in the clean gas feed line and provided with a control valve (22). 7. Particle separator according to one of claims 1 to 6, characterized in that the plate electrode (10) made of metal is connected to a measuring device. 8. Particle separator according to one of claims I to 7, characterized in that the plate electrode (10) is provided with a cleaning device.