SE453159B - DEVICE INSTALLING AN INSULATOR IN AN ELECTROSTATIC DUST DISPENSER - Google Patents

Abstract

The present invention relates to an arrangement in an insulator (4) which forms part of an electrostatic dust separator and which has an insulator part provided with one or more first holes (17) through which a gas flow can pass for the purpose of reducing or eliminating the collection of dust on the inner wall sections (4a) of the insulator. Located downstream of the first holes (17) as seen in the direction of gas flow, is one or more turbulence generating devices (20). A container (21) is arranged adjacent the aforementioned insulator part and has a configuration such that all of the first holes (17) in the insulator part open into the container. The container surface facing away from the aforementioned insulator part is provided with a plurality of second holes (22) which discharge or open upstream of the turbulence generating device (20).

Description

453 159 2 The previously known insulator has a cylindrical body, the upper planar horizontal part of which cooperates with a plate, intended to hold the emission electrode. A number of holes extend through the plate, intended to be able to allow air under pressure to pass through said holes, and to pass along the interior of the insulator and down to the electrostatic precipitator.

The prior art device has an over-heel oriented cover, defining a first chamber, formed with a non-return valve, so arranged that it ensures only one air passage direction, namely down towards the dust separator. Around this cover or hood there is a further cover or hood to form a second chamber, to which compressed air is connected via a connecting line.

The prior art also includes a device shown and described in U.S. Pat. No. 3,033,918, in which the insulators are heated and thermally insulated from the environment to reduce the risk of condensation of water or acid on the surface of the insulator.

Here, a cone-shaped insulator is indicated, the upper part of which cooperates with a plate and this plate is formed with holes, placed along an arc of a circle symmetrically in relation to the insulator.

Through a valve, an overpressure could be applied to a first chamber and in that case an air flow could pass through the holes. Such an air flow would give rise to reversing vortices, which would contribute to bringing contaminants from the dust collector and into the interior of the insulator, to accumulate against the interior of the insulator, like a truncated cone-shaped surface.

However, the conformation of the insulator helps to make the enclosure of the first chamber narrower at its upper part, taking into account sufficient insulating distances.

Finally, it should be mentioned that in Swiss Patent Specification 443 227 it is known to take measures to effect a purge of the inner surfaces of the insulator by inserting elongate nozzles into a plate and formed therein, so that they form, at a distance downstream of the plate, a rotating air flow which in combination with an overpressure ensures that particle-laden gas mixture does not penetrate into the insulator area. 3 453 159 DESCRIPTION OF THE CURRENT INVENTION TECHNICAL PROBLEM Taking into account the prior art, as expressed by the above-mentioned patents, it appears to be a technical problem to be able to create a device with simple means, as with a limited gas volume, in relation to that required in the previously mentioned publications, enables efficient cleaning of and effectively reduces the tendency for dust accumulations towards the inner wall portions of the insulator.

The concept of gas volume must include not only a mixture of gases but also clean air.

It is especially a technical problem to ensure a unidirectional flow through the entire insulator with a low volume flow through the narrower end of an insulator, in the form of a truncated cone, without the need for areas with a backward gas flow, which can lead to dust from the inside of the dust collector to the inner walls of the insulator and get stuck there as electrically conductive deposits.

It is further a technical advantage to create such conditions that the amount of gas used can be kept low, as this has the consequence that a large amount of heat energy can be saved, since the gas stream used must be hot, and exceed the temperature at which condensation is precipitated at the inner wall portions of the insulator.

It must also be considered a technical problem to be able to come to the realization that despite a considerable reduction of the required gas flow, for example by about 75%, the used gas flow would be sufficient if, after passing through the holes, it could be allocated a controlled vortex formation and essentially a helical and helical rotation around a center line assigned to the insulator.

It is a further technical problem to come to the realization that the above-mentioned technical problems could also be assigned a solution to already installed electrostatic precipitators, by applying in the interior of the insulator a prefabricated unit, including such vortex-forming means, which can allocate a gas volume. rotation. 453 159 4 Furthermore, it must be considered a technical problem to come to the realization that when using a prefabricated unit and vortex-forming means and while using first holes in the portion of the insulator intended for supporting the electrode, the unit, in the form of a container, be formed at its surface facing from the batch with a plurality of other holes, which will then open upstream of said vortex-forming means.

It is also a qualified technical problem to realize for air-saving purposes that the other holes in the surface of the container facing from the batch must in that case be several in number and assigned smaller cross-sections than the first holes in the batch and be evenly distributed next to resp. vortex-forming organs.

Furthermore, it is a technical problem in the construction of a unit having vortex-forming means, of the above-mentioned nature, to create an external shape for the container, which means that it does not have surfaces, but such a shape that certain parts become inclined to have a disturbing field strength concentration but still create conditions to easily create vortex-forming organs.

It is also a technical problem to be able to create vortex-forming means by simple means which, for this technical field, provide a sufficiently efficient rotating vortex formation around the center line of the insulator and above all for cone-shaped insulators create conditions for rotating vortex-formed currents so that dust accumulations are eliminated against the inner parts of the insulator belonging to the insulator, against the inner divergent of the dust separator.

In addition, it must be considered a technical problem to be able to create conditions with simple means for a continuous heating of utilized air stream, alternatively a utilized gas stream may consist of gaseous medium purified in the electrostatic separator from solid particles.

Furthermore, it must be considered a technical problem to be able to realize that efficiently acting vortex-forming means in this technical field can actually have a very simple design, such as one or more guide rails.

It is also a technical problem to, despite simple construction of the vortex-forming members, still create conditions for a substantially uniform rotation of the gas stream around the axis of symmetry of the insulator despite an increasing cross-section of the insulator in the direction of travel of the gas stream towards the dust collector. THE SOLUTION To solve the above-mentioned technical problems, the present invention is based on a device, in the case of an insulator included in an electrostatic precipitator, preferably an electrode and then an emission electrode. For the latter application, it is formed with an upper for the upper attachment of the electrode and for its supporting intended portion. This portion is horizontally oriented and formed with one or more first holes, to allow through them a gas stream to pass through the interior of the insulator and into the dust collector, in the sense of reducing or preferably eliminating a tendency of dust accumulation through this gas stream towards the insulator belonging to the inner wall portions.

The present invention indicates that in the direction of the gas flow, downstream of these first holes in the upper portion, there is one or more vortex-forming means, for example constituting a guide rail obliquely oriented in relation to the direction of the gas flow through the first heel, which assigns the gas flow or the air mass a rotating rotational movement for flushing the insulator wall.

It has proved advantageous to provide a container designed as a prefabricated unit, which should be arranged next to the portion and attached to the lower edge of its horizontal surface and also assigned such a shape that all first large holes in the portion will open into containers.

The horizontal surface of the container facing the batch must also be formed with a plurality of other smaller holes and these must open upstream and in the immediate vicinity of said vortex-forming means.

Also within the scope of the invention is the possibility of allowing the other holes in the surface of the container facing the lot to be considerably more in number and assigned smaller cross-sections than the first holes in the lot and otherwise dimensioned so that a certain overpressure will prevail in the container. internal. This ensures a uniform speed distribution in all holes out of the container.

The present invention particularly teaches that resp. vortex-forming means shall consist of a guide rail obliquely oriented in relation to the direction of the gas flow through the first holes or the second holes; This can advantageously be flat or substantially flat and a resp. guide rail assigned to the plane, the plane may be oriented so that the plane forms an angle between 20 and 700 in relation to said air flow direction, preferably about 45 °.

The guide rail can have a very simple shape, for example flat rectangles.

Furthermore, it is proposed that the vortex-forming means are arranged so as to produce a substantially uniform rotation of the gas stream about an axis of symmetry assigned to the insulator.

In practice, it is advisable to let the other holes, as well as the first holes, be circularly designed. In the case of circularly formed holes, it is proposed that the center distance between adjacent holes should be less than twice the diameter of the respective hole. hole. The other smaller holes must be evenly distributed along the entire surface of the container facing the lot.

The number of vortex-forming organs should advantageously exceed four, but should for practical reasons usually be less than twelve. Practical tests indicate that eight vortex-forming organs can be considered satisfactory.

The container designed as a separate and prefabricated unit shall have a circular cross-section, where the vortex-forming means are arranged to extend between a holding device for an emission electrode and the periphery of the container.

Finally, it is indicated that a limited gas stream should be continuously supplied to the dust separator through said hole and the vortex-forming means and that the gas stream is heated by a heating device, preferably an electrically driven device.

It has been found to be particularly advantageous to apply the indicated device to a supporting insulator for an emission electrode (or precipitation electrode if the emission electrode is grounded) with a diverging shape extending from the vortex-forming means.

ADVANTAGES The advantages that can mainly be considered to be associated with a device in accordance with the present invention are that in this way conditions have been created for creating a conditions with a small gas stream to reduce or eliminate tendencies to dust accumulation towards the insulator belonging to the inner wall portions. -a - a - p-n - p - u- What can primarily be considered as characteristic of a device in accordance with the present invention is stated in the characterizing part of the following claim 1.

BRIEF DESCRIPTION OF THE DRAWINGS A presently proposed embodiment, having the features significant to the present invention, will be further described with reference to the accompanying drawings therein; figure 1 shows in side view a previously known device, figure 2 shows in side view and section a device according to the present invention, with an insulator supporting an electrode included in an electrostatic precipitator, having a plurality of vortex-forming means, figure 3 shows a prefabricated container having said vortex-forming means in side view, figure 4 shows the container according to figure 3 in a horizontal projection and figure 5 shows an air flow heating device.

DESCRIPTION OF THE CURRENTLY FURNISHED EMBODIMENT Referring to Figure 1, there is shown in side view a previously known device with an emission electrode supporting insulator included in an electrostatic precipitator, according to U.S. Pat. No. 3,531,918.

Figure 1 shows how an emission electrode 1 is attached to a support member 2, and where this support member passes through a sleeve 3 and an insulator 4. The insulator 4 is located over an upper cover plate 5 for the electrostatic precipitator. 453 159 8 The insulator 4 carries at its upper part a horizontally oriented plate 6 and which plate 6 is formed with a number of large holes 7. The number of holes here can be four. The plate 6 is arranged to support and hold the member 2 and for better air distribution a washer 8 is used. This washer 8 is provided with a number of small holes 9, oriented in connection with the holes 7, in order thereby to allow an air flow to pass through said holes 9. and 7 through the insulator 4, the tube 3 and into the electrostatic precipitator as a substantially laminar flow.

A first hood or cover 10 is oriented over the washer 8 and attached to the plate 6 to define a space 11 which is pressurized and via a non-return valve 12 air in a space 13, delimited by an outer hood or a casing 14 can be caused to gain access to the space 11. The air is connected via a connection 15 from a source of overpressure (not shown).

The present invention now specifically provides, as illustrated in Figure 2, that the insulator 4 should cooperate at its upper portion with a horizontally oriented plate 16 and this plate 16 is formed with holes 17 with a diameter of 10-15 mm. The plate 16 also holds the member 2, for the emission electrode, via a nut 18.

In order to reduce the air flow allowed to pass through the holes 9 and 7 of Figure 1, and despite a 50-70% reduction, still eliminate dust accumulations against the inner wall portions 4a of the insulator 4, the present invention directs that in the direction of the air flow " Counted downstream of these first heels 17, there are one or more vortex-forming members 20. In the exemplary embodiment, it is illustrated that eight vortex-forming members are symmetrically arranged around the device 2.

The present invention provides in particular a prefabricated container 21 and this container is attached at one part 21a to or arranged to the horizontal underside of the plate 16 and the container is assigned a cylindrical shape and that all first holes 17 in the portion 2 open into the container. The flat surface 21b of the container facing from the portion 16 is formed with a large second hole 22, opening immediately upstream of said vortex-forming member 20.

The second holes, in the surface of the container 21 facing away from the portion 16, are several in number and assigned smaller cross-sections than the first holes 17 in the portion. Specifically, indicate that the first holes are formed circularly and oriented DW 9 453 159 concentrically with respect to the device 2 in a single row, while the second holes 22 are evenly distributed over the lower surface 21b of the container 21.

The invention further indicates that the other holes are circularly shaped and oriented with a center distance between them less than twice the diameter and this is best seen from Figure 4. It should be practical not to let these other holes have a diameter larger than 10 nm and preferably they should be between 2 and 6 mm.

The respective vortex-forming means 20 consist of a plate or plate 23 obliquely oriented in relation to the direction of the air flow through the first 17 holes or the second 22 holes.

Each plate is rectangular in shape, but can of course also be square.

If the respective plate is assigned a plane "A", in figure 3, then this plane should be arranged to form an angle between 20 and 700 in relation to said air flow direction and this angle has been given in reference figure in figure 3 the reference designation "a". The exemplary embodiment illustrates that the plane "A" assumes an angle of 45 ° in relation to the direction of the air flow.

Figure 4 further shows that the container 21 has a circular cross-section and that a resp. the edging portion 23a of the vortex forming means extends radially between a holding device 2 for an emission electrode and the periphery 21c of the container and with the upper surface or edge oriented in the radius of the container.

Finally, it is indicated that the air flow through the connection 15 in Figure 1 could be modified, since the air flow according to the present invention is considerably smaller than required in the prior art and therefore the air flow can be supplied continuously via an air flow heating device 25, consisting of a tube serving as a protection for an electrically heated coil 26 oriented inside the tube and around which coil 26 an air stream via the connection 15 'is passed before this air stream enters the space 13. The reference numeral 27 illustrates the connection terminal for electric supply voltage.

The vortex-forming means must be so designed that when a plurality of air jets (through the holes 22) abut against the plate 23, they must be deflected and "roll" 453 159 towards the wall portion 4a of the insulator, after which the whole air mass in the interior of the insulator has a rotating clockwise travel. and thus a cleaning of the insulator wall 4a takes place.

The air stream intended for heating should be constituted by a gas stream purified and previously heated in the dust collector, so that the required heat energy supply can be made via the device 27.

The invention is of course not limited to the above-mentioned exemplary embodiment, but may undergo modifications within the scope of the inventive concept illustrated in the appended claims.

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Claims (13)

1 '453 159 PATENT CLAIMS Device at an insulator included in an electrostatic precipitator (4), formed with an upper portion (16), formed with one or more front holes (17) to allow a gas stream to pass through them and meaning to reduce or eliminate accumulations of dust against the insulator belonging to the inner wall portions, characterized in that in the direction of the gas flow calculated immediately downstream of these first holes (17) in the upper portion (16), there are one or more vortex-forming means (20), for example constituting a guide rail (23) obliquely oriented in relation to the direction of the gas flow (P) through the first holes (17), which assigns the gas flow or the air mass a rotating rotational movement for flushing the insulator wall (4a). Device according to claim 1, characterized in that a container (21) is arranged to the portion (16) and assigned such a shape that all the first holes (17) in the portion (2) open into containers, and that the container surface facing the portion (21b) is formed with a plurality of second holes (22), opening upstream of said vortex-forming means (20). Device according to claim 2, characterized in that the other holes (22) in the surface of the container (21) facing from the portion are several in number and assigned smaller cross-sections than the first heels (17) in the portion. 4. Device according to claim 1, characterized in that resp. the guide rail consists of a flat or substantially flat plate. 5. Device according to claim 1 or 4, characterized in that a resp. the guide rail assigned plane (A) is oriented in a direction forming an angle between 20 and 700 in relation to said gas flow direction, preferably about 450. 6. Device according to claim 1, characterized in that the vortex-forming means (20) are arranged to give a substantially uniform rotation of the gas flow around an axis of symmetry assigned to the insulator. 453 159 W Device according to claim 2, characterized in that the second holes (22) are circular and oriented with a center distance between each other of less than twice the diameter. The device according to claim 2, characterized in that the other holes (22) are evenly distributed along the entire surface of the container facing from the batch. Device according to claim 1, characterized in that the number of vortex-forming means (20) exceeds four but is less than twelve. Device according to claim 2, characterized in that the container (21) has a circular cross-section and that the vortex-forming means (20) extend between a holding device (2) for an emission electrode and the periphery of the container (21c). . Device according to one of the preceding claims, characterized in that a gas stream is continuously supplied via a gas stream heating device (25). Device according to one of the preceding claims, characterized in that the inner surface of the insulator has a divergent shape extending from the vortex-forming means. Device according to one of the preceding claims, characterized in that the insulator is designed as a support for an electrode, preferably an emission electrode. .u