AT15529U1 - PRECIPITATED TUBE BUNDLE FOR WET ELECTROFILTER - Google Patents

Abstract

The present invention relates to a Niederschlagrohrbündel for wet electrostatic precipitators, which are used for the separation of dusts, aerosols or undesirable gases, such as hydrogen chloride, hydrogen sulfide, sulfur oxides, nitrogen oxides, nitrides or similar, harmful components from exhaust gases and gas mixtures. The precipitation tubes consist mostly of polyolefins, in which optionally the conductivity of the plastic increasing, powdery additives are embedded and wherein centrally in the axial direction of the precipitation tubes each have an electrode, in particular a spray electrode is arranged. The invention is characterized in that a grounding device (4, 5) of electrically good conductive material is arranged on at least one end face (2) of each precipitation tube and the individual grounding devices (4, 5) of an end face plane with each other and with a central current dissipation conductive are connected.

Description

Description: The present invention relates to precipitation tube bundles for wet electrostatic precipitators for filtering out dusts or aerosols or undesired gases, such as hydrogen chloride, hydrogen sulfide, sulfur oxides, nitrogen oxides, nitrides or similar harmful components from exhaust gases and gas mixtures.

Wet electrostatic precipitator preferably consist of a bundle of individual rainwater pipes. These precipitation tubes are preferably made of plastic and have an electrode in its axis center. Plastic is therefore given preference over other materials, in particular metals, since it is less expensive and at the same time chemically stable. If the filter is in operation, the inner surfaces of the precipitation tubes are wetted with a flowing, electrically conductive liquid which serves as a current path for deposition from the gas flow flowing in the axial direction in the precipitation tube. The liquid can be introduced via spraying, by condensate and / or by flowing over the end face of the tubes.

Between the coaxial electrode and the tube inner wall, a strong electric field is formed by applying a high voltage. As a result, the undesirable constituents in the gas stream, in particular the dust particles, are ionized, so that they follow the electric field lines to the inner wall of the pipe, where they stick to the liquid droplets and are excreted via the liquid flowing out at the pipe outlet end.

In normal operation, the pipe inner surfaces are evenly wetted with the washing liquid and the current path is thus uniform. In the case of fluctuations in the gas flow, the gas composition or the amount of gas, however, the precipitation tube inner surfaces may partially dry out, as a result of which electrical flashovers may occur, which can lead to severe burns in the tube wall. In order to avoid damage to the pipes by flashovers, it is known to ground the pipes. In this case, the grounding engages at least at the outlet end of the gas stream, but preferably at both ends of the pipe in order to achieve as balanced as possible a potential on the pipes.

From EP 1 098 710 B1 it is known to hold one-piece pipes by an upper support collar and a lower guide ring in positive engagement. The individual tubes are held by interconnected half pipe elements. By means of the support sleeve, the tube bundle is suspended in a housing. The lower guide ring is used to distance the pipes and to connect the pipe ground to the outside. Each tube of the precipitation tube bundle has an upper grounding as an inner ground and a lower ground, which is welded into the surface of the tube and is connected to the lower guide ring. The groundings of the individual tubes are electrically connected to each other. In this case, the inner grounding of each tube consists of a polypropylene injection-molded ring with four graphite inserts and a Graphitfolienummantelung. The bottom ground of each tube consists of a carbon cord or a carbon tube.

From DE 103 34 348 A1 a precipitation pipe for a wet electrostatic precipitator is known, in which the precipitation pipes are equipped with an electrically conductive plastic coating on the pipe inside. The outer tube is made of non-conductive plastic, e.g. made of polypropylene, which has very good mechanical properties. The thin inner tube layer is made of polypropylene with electrically conductive additives. This tube is produced by co-extrusion in one operation. In the case of a drying of the surface, the conductive plastic coating temporarily takes over the task of the current path. Since conductive plastic also has a relatively high sheet resistance (103 to 106 ohms), it is also possible here to dispense with the already well-known graphite or platinum lead for conducting current. In order to enable the grounding of all tubes, the electrically conductive inner coatings of adjacent tubes are conductively connected to one another by means of graphite bridges or graphite clamping pieces at the tube ends. The graphite clamping pieces are conductively connected to a grounding plate.

The graphite bridges are composed of graphite discs and thus conductively connected to the tube wall surrounding graphite foils together, wherein the graphite discs are positively embedded in the outer tube. The graphite foils of adjacent tubes are in physical contact. However, this type of grounding is bound to the presence of a conductive inner coating, since in the case of the use of conventional polyolefin tubes, which have no conductivity, or if embedding graphite, the difference in conductivity between the tube material and graphite disc particularly promotes flashovers in this area which in turn can lead to damage due to local overheating, in extreme cases even to a disintegration of the graphite disks and thus to a life-threatening dangerous reduction of grounding.

Both grounding systems come from the same developer and also have the disadvantage that they are complex and expensive to manufacture and prone to failure in operation, i. E. they do not provide safe protection against damage to the precipitation pipes by electric flashovers. This is also the reason that in both systems, the arrangement of the precipitation tubes in the tube bundle takes place so that individual tubes can be taken out of the tube bundle and replaced by new tubes. Depending on the application, the individual tubes can have a diameter of up to 350 mm and a length of up to 6 m. With these dimensions, the replacement of individual tubes from a vertically arranged tube bundle is somewhat difficult.

In DE 102 24 330 A1 a wet electrostatic filter is described with grounding system consisting of bundled, tubular collecting electrodes made of plastic with axially arranged, suspended spray electrode, which are grounded at the top and bottom. In this case, all the collecting electrodes are interconnected by means of electrically conductive laminated plastic rings, these plastic rings are pushed and fitted tight fitting over the collecting electrodes. However, this system does not solve the problem of localized flashover when tearing the liquid film on the inside of the pipe. The further developments of this earthing system, disclosed in DE 103 11 686 A1, DE 10 2004 001 463 A1, have the same problem. In addition, the electrically conductive lining is anchored by scarfing in the thermoplastic surface of the outer ground frames. When scarfing but the material structure of the surfaces can be destroyed and thus the chemical resistance can no longer be guaranteed, as the inventor himself in its further development, disclosed in DE 10 2007 031 702 A1 explained. The Außenerdungszarge described therein with an electrically conductive carbon fiber or graphite strip in a trough but solves the mentioned problem in the demolition of the liquid film on the tube inside just as little.

The present invention therefore has the task of grounding a wet electrostatic precipitator in the form of a bundle of precipitation tubes with internal, axially arranged electrodes so that the production of the grounding devices is made easier and less expensive than is the case with the known devices and a deterioration of the operation of the earthing device is practically excluded by electric flashover.

This object is achieved by at least one, preferably on both faces of the precipitation tubes by electrically good conductive metals, metal alloys, carbon fibers, graphite tapes, graphite, graphite cords or highly conductive composite materials, a current path for voltage dissipation is created and all in a face plane lying grounding devices with each other and are connected to a central discharge conductive.

The precipitation tubes can be round or polygonal, in particular honeycomb-shaped. They are preferably made of a polyolefin, in particular of polypropylene, wherein the material, a conductive additive, such as graphite may be added to make the pipe material itself more conductive. By avoiding good conductive

Deployment is the probability of flashovers along the precipitation pipe everywhere the same size and essentially only depends on the operating parameters.

At the same time a secure contact with the effluent washing liquid is ensured at the lower end face.

The front sides of the precipitation pipes are particularly well suited for the attachment of a ground, since they not only - as in the peripheral around the tube bundle ground the case - touched only the outer tubes, but all tubes, so the central tubes, which be supplied with a current path to the outside without further conductive interconnection. Another advantage is that the end faces have a direct connection to the inner surface of the tubes, so that at least at the lower end face is a wetting with the washing liquid.

The grounding device according to the invention may have different shapes and consist of different materials. It may consist of a metal, a metallic alloy, carbon or a highly conductive composite material and may take the form of a band, a rod, a string, a wire, a foil, a flat profile, an L-profile, a U-profile, another profile, a cord, a fleece, a net or a combination of these devices.

The invention is explained below with reference to the figures. These figures show only two different variants of the device according to the invention. However, it goes without saying that the present invention is not limited only to the illustrated variants, but also includes all variants and variations as they emerge from the description and in particular from the claims. In the figures: Fig. 1 shows an oblique view of a bundle of honeycomb precipitation tubes, as used for the production of a wet electrostatic filter, with the part of the grounding device according to the invention; Fig. 2 is a view of the end face of the tube bundle of Fig. 1; Fig. 3 is an oblique view of a tube bundle section with a part of a flange plate with laminated conductive fleece, which surrounds the end faces of the precipitation tubes and slightly covers the inside of the tubes in the edge region; FIG. 4 shows a side view of the device according to FIG. 3.

In Fig. 1, a precipitation tube bundle can be seen, which is made of several honeycomb segments 1 according to the method described in the AT 50040/2015 Applicant. Parts of the end faces 2 of the precipitation tube bundle are covered with grounding devices 3, wherein the grounding devices 3 form continuously extending current paths 4 over the plane of the end face 2. Although it is necessary for a good operation of the grounding that each precipitation tube is well grounded, but not necessarily the entire end face is necessary, the grounding device 3 was formed here as evenly over the plane of the end faces 2 extending leifähige current paths 4, as well from Fig. 2 clearly visible.

The covering of the end faces of the precipitation pipes can be full-surface or partial area. In Fig. 1, the groundings of individual contacting tubes form continuous longitudinal lines, but between which there are no cross-connections. Similarly, the grounding of round tubes may look, and it is also possible that the lines of the grounding device 3 partially have no face contact.

Grounding devices can in principle have very different shapes. So are films, cords or cords, rod-shaped, L-, U- or other profiles but also nonwovens, fabrics or networks, or conductive coatings, such as conductive coatings conceivable. They may be mounted on the end face 2, they may comprise the end faces of the precipitation tubes and they may extend slightly beyond the end face on the inner surface of the

Rainwater pipes extend. They thereby form an even better connection to the pipe inner surface.

Especially with round downpipes, it is conceivable that these lie with the end in breakthroughs of a flange plate and the grounding device, which is for example a good conductive film and / or a good conductive fabric with or without reinforcing insert covers the flange, the end faces the rainwater pipes engages and slightly engages the precipitation pipes. Again, the covering of the flange plate and the end surfaces may be formed over the entire surface or part of the area.

In the grounding device 5 in Fig. 3 is, for example, a laminated nonwoven of electrically good conductive material, which covers the flange 6, the end faces 2 of the precipitation tubes 8 and slightly the inner surface 7 of the precipitation tube 8. 9 represents the connection to the current discharge of the system.

In a further, not shown variant of the invention, a groove is milled into the end face 2 of the precipitation tubes and the grounding device lies in the groove and either ends flush with the end face or protrudes slightly out of the groove. A further advantageous development provides that transverse grooves are milled to the circumferential groove, which are filled with the grounding device and have a direct contact with the pipe inner surface. It is of minor importance, if all grooves and transverse grooves are filled with the grounding device or only parts thereof. Often it is sufficient if the grounding device runs through the end face plane of the precipitation tube bundle in a quasi-line shape, as already evident from FIG.

The grounding device may be such that it does not touch the full length of an end face but in places there is no contact with this. This embodiment is particularly advantageous if the coefficient of thermal expansion between the pipe wall and the material of the grounding device varies in size, wherein usually the thermal expansion coefficient of the grounding device is smaller than that of the pipe wall. In this case, the non-contact portion of the grounding device serves as a strain bridge. This variant can be used, for example, in a bundle of round tubes.

In principle, it is secondary to the operation of the present invention, whether the tubes are round or polygonal. Preferably, however, the precipitation tubes are hexagonal and honeycomb-shaped to form the tube bundle. Honeycomb tube bundles have a much larger separation area with the same space requirements as circular tubes and can, as is apparent from DE 20 2016 101 150.7, be produced with significantly lower material costs, whereby the total weight of the tube bundle is significantly reduced.

The present invention is distinguished by its particular advantages over the well-known from the prior art grounding devices for rainwater pipes of wet electrostatic precipitators: The variety of design options in a situation on the face of the precipitation tubes allows a perfect adaptation to the geometry of the system and the prevailing operating parameters. The material and production costs are considerably lower or simplified and the reliability of the grounding device is increased.

Claims (14)

claims 1. precipitation tube bundle for wet electrostatic precipitator for the separation of dusts, aerosols or unwanted gases, such as hydrogen chloride, hydrogen sulfide, sulfur oxides, nitrogen oxides, nitrides or similar, harmful components from exhaust gases and gas mixtures, the precipitation tubes are made of polyolefins, in which optionally the conductivity of the plastic increasing , Powdered aggregates are embedded and wherein in the axial direction of the precipitation tubes in each case an electrode, in particular a spray electrode is arranged, characterized in that arranged on at least one end face (2) of each precipitation tube a grounding device (4, 5) of electrically good conductive material is and the individual grounding devices (4, 5) of an end face plane are conductively connected to each other and with a central power dissipation. 2. precipitation tube bundle according to claim 1, characterized in that the grounding device (4, 5) covering the end face (2) of the precipitation tube over the entire surface or part of the area. 3. precipitation tube bundle according to claim 1 or 2, characterized in that the grounding device (4, 5) comprises the end face (2) of the precipitation tube. 4. precipitation tube bundle according to claim 1 or 2, characterized in that the grounding device (4, 5) lies in a groove which is milled into the end face (2) of the precipitation tube. 5. precipitation tube bundle according to claim 4, characterized in that the groove is connected by means of transverse grooves with the tube inner side (7). 6. precipitation tube bundle according to claim 5, characterized in that in the transverse grooves parts of the grounding device (4, 5) are inserted. 7. precipitation tube bundle according to one of claims 1 to 6, characterized in that the grounding device (4, 5) runs through the end face plane of the precipitation tube bundle in a line or net shape. 8. precipitation tube bundle according to one of claims 1 to 7, characterized in that the grounding device (4, 5) bridges between adjacent precipitation tubes (8). 9. precipitation tube bundle according to one of claims 1 to 8, characterized in that the grounding device (4, 5) a band, a rod, a flat profile, an L, U or other profile, a string, a cord, a wire, is a woven fabric, a net, a coating, a non-woven, a grid, a foil, a plate or a combination of two or more of these devices and consists of electrically highly conductive material. 10. The precipitation tube bundle according to claim 9, characterized in that the grounding device consists of a metal, a metallic alloy, graphite, a carbon fiber, or a highly conductive composite material. 11. precipitation tube bundle according to one of claims 1 to 10, characterized in that the end portions of the precipitation tubes in openings of a flange plate (6) and the grounding device (4, 5) has a good conductive film and / or a highly conductive fabric (5) or without reinforcing insert which covers the flange plate (6) and the end faces (2) of the precipitation tubes and at least partially engages the precipitation tubes (8) and slightly covers the tube inner surface (7). 12. precipitation tube bundle according to claim 11, characterized in that the highly conductive film and / or the highly conductive fabric (5) the flange plate (6) partially and the end faces (2) of the precipitation pipes completely or partially covered and in the precipitation pipes (8) intervenes. 13. precipitation tube bundle according to one of claims 1 to 12, characterized in that the precipitation tubes (8) have a circular, a polygonal or a honeycomb-shaped cross-section. 14. precipitation tube bundle according to one of claims 1 to 13, characterized in that the precipitation tube bundle has no outer sheath and distributed over the length of the precipitation tube bundle has several other grounding devices. For this 2 sheets of drawings