DE2507751A1 - Electrostatic filter - combining filter and electrostatic precipitator for removal of microorganisms etc. from air - Google Patents

Abstract

Electrostatic fine filter for gaseous media in which the medium flows through an electric field, has a large number of individual channels running in the direction of flow, the boundary walls of which are parallel to the flow and at least partly constructed of an electrically conducting fibre fleece and connected to one pole of a high tension DC source, the opposite pole of which is connected to a metal screen which in turn is clamped in front of as well as transversely to the individual channels. Incorporates a conventional filter of selected pore size which is also an electrostatic filter, whereby very fine particles of size down to 0.0008 um including viruses bacteria and other microorganisms can be removed from an air stream.

Description

Electrostatic fine filter for gaseous media The invention relates on an electrostatic fine filter for gaseous media, in which the medium flows through an electric field.

Electrostatic filters have oppositely polarized electrodes, an electric field is built up between them by applying a high DC voltage which is flowed through by the gas to be filtered.

Foreign bodies contained in the gas become at least partially electrostatic attracted and deposited on the electrodes. To improve the filter effect is it is known to use a fiber material transversely to the direction of flow of the gas to be filtered or to stretch out fleece, in which further, especially small particles settle, and which is cleaned or renewed from time to time.

It has been shown, however, that these known fine filters are still so a lot of residual particles let through that they are for certain applications, for example in the medical sector, are unsuitable or unsuitable. The object of the invention is to provide a more effective electrostatic fine filter to accomplish.

According to the invention, this object is achieved by a large number of in the direction of flow running individual channels, whose flow-parallel boundary walls at least are partially formed by an electrically conductive nonwoven fabric with the one pole of a high DC voltage source is connected, the opposite pole of which is connected to a Metal grid o. The like. Is, and that in turn in the direction of flow in front of and across is stretched to the individual channels, solved.

Compared to the state of the art, this solution initially has the advantage that that the fleece is not only flowed through once by the gas to be filtered, but in The form of a duct lining accompanies the gas flow over a considerable distance. Since the fiber fleece is also conductive, it develops through its connection with the one high voltage pole itself electrostatic forces, which practical all particles present, including viruses, bacteria, microorganisms and the like pulls out.

For the build-up of the electrostatic field it can be advantageous if part of the walls is made of metal. A particularly large surface can be achieved if these walls are arched like corrugated sheet metal and arranged in such a way that the plate-shaped fiber fleece between the opposite wave crests adjacent corrugated metal is clamped.

In this context, it can also be advantageous to use the fiber fleece Wrap around the corrugated sheet metal parts in a meandering shape.

It can also be advantageous to use two fine filter assemblies in tandem to be arranged one behind the other in the direction of flow. This ensures that at the end of each individual channel there is still a transverse fiber fleece layer flowing through it must be, which particles, for example by vibrations from the fine filter have been solved, catches safely. Alternatively, a single fine filter assembly can be used arranged and behind it an electrically conductive one connected to the high-voltage field individual nonwoven web be stretched. To the flow resistance of the flowing through To neutralize the gas, this nonwoven web can be supported by a grid element be.

It can also be advantageous to generate a pulsating electric field Build high DC voltage source. Pulses of, for example, can be used as the operating frequency 50 Hz or higher frequency can be used.

The high voltage can for example be in the range between 1.6 and 3.2 kV.

Further details and advantages of the invention can be found in the following Description of a preferred embodiment in connection with a drawing can be removed. 1 shows a section through an in a flow channel built-in electrostatic fine filter, Fig. 2 is a front view in the direction of flow of a single fine filter assembly from the filter of Fig. 1, and FIG. 3 shows a partial section through a plane 3-3 of FIG. 2 in an enlarged manner Scale.

In the embodiment described below, the inventive Fine filter in an expansion of an air duct designed as a dismountable housing 12 16 installed, which can be used, for example, for an air conditioning system or

belongs to the ventilation system of a hospital, its operating theaters must be supplied with finely filtered and bacteria-free air. The housing 12 is screwed to a funnel-shaped connection part 14 of the air duct 16 and contains two fine filter assemblies arranged transversely to the direction of air flow indicated by arrows 10 and a negative electrode assembly arranged in front of it in the direction of flow 24.

The fine filter assemblies 10, which are based on FIGS. 2 and 3 below are explained in detail, are electrically conductive by spacers 22 connected to one another and as a tandem assembly by means of several isolators 18 against High voltage insulated, fastened to the housing 12 by means of screws 20 and by means of a positive connection line 26 to the positive connection of a not shown pulsating high DC voltage source connected.

According to FIG. 1, the negative electrode assembly 24 consists of a electrically conductive frame 40, between the transverse to the flow direction of the to be filtered Gases several wires 38 are stretched. The entire frame 40 with the wires 38 is by means of a negative connection line 28 to the negative connection of the mentioned pulsating high-light voltage source connected. Furthermore is the entire negative electrode assembly 24 electrically isolated by a plurality of insulators 18 connected to the adjacent fine filter assembly 10. Thus, the entire fine filter Pre-assembled as an assembly and inserted into the housing 12 or for cleaning and the like. Like. Be taken.

To prevent the side between the assemblies of the filter When air flows past, the assemblies are either inserted gas-tight in the housing or by circumferential sealing strips made of electrically insulated material from the Housing sealed.

As an alternative to the embodiment shown in Fig. 1, it is also possible only a single fine filter assembly 10 with a negative electrode assembly 24 to combine, the omitted filter assembly through a transverse to the air flow direction Tensioned electrically conductive fiber fleece layer may be replaced or may be missing can. It is also connected to the positive lead and against the air flow pressure is supported by a grid or the like. This grid is either constructed electrically isolated or also connected to the positive connection line. Basically, the rear filter assembly or fiber fleece layer comes in the direction of flow the task to increase the fine filter effect even more and certainly particles to catch the vibrations or the like from the first fine filter assembly could have been resolved.

The structure of an individual filter assembly 10 will now be based on Figures 2 and 3 of the drawing are described in more detail. In one to the outside isolated rectangular frames 30 are a variety of wave-shaped Electrode strips 32 attached in parallel and at equal distances from one another. The gap between the vertices of adjacent wave-shaped electrode strips 32 is straight so wide that a fiber fleece 34 can be frictionally interposed. By doing enlarged section of Fig. 3 can be seen that each adjacent electrode strips 32 are offset from one another in the direction of flow. Taking advantage of the A single fibrous nonwoven web 34 meanders around all electrode strips 32 looped around, so that in the front and rear view of the fine filter assembly 10, every second electrode strip 32 is visible and the intermediate one is covered by the nonwoven web 34. Between the Nonwoven fabric 34 and the wave-shaped channels of the electrode strips 32 become numerous narrow flow channels formed for the air to be filtered.

The fiber fleece is in the present exemplary embodiment a fibrous paper with glass particles of a grain size held by the fibers of 8 ». This fiber fleece 34 is impregnated with an electrically conductive material or treated with a conductive varnish.

This ensures that the entire fiber fleece has the same potential occupies like the adjacent wave-shaped electrode strips 32, which in the present Trap connected to the positive connection line 26 of the high DC voltage source are. The grain size in the fiber fleece can be adjusted depending on the intended use of the fine filter choose freely. According to the current state of development, the grain size can be up to reduce it down to about 0.3r, and it plays one, even if not according to the invention decisive role in the collection effect against the smallest dust particles or Microorganisms.

In the case of the fine filter assembly 10, the nonwoven fabric 34 carries because of its Surface roughness in connection with the electrical charge in particular for particle binding. The grain size of the glass parts in the fiber fleece is based on this Reasons for the filter effect of subordinate importance. A special safety factor the fine filter according to the invention provides the partitioning of the filter channels between the electrode strip 32 through the meandering laid around nonwoven fiber web. Another advantage of the fine filter assembly 10 according to the invention is that they have a relatively small size and low flow resistance has an extremely high filter effect, even against the smallest particles, because it is able to separate particles up to a size of 0.0008m, i.e. up to the order of magnitude in which viruses, bacteria and other microorganisms can be found.

The negative electrode assembly already described in connection with FIG 24 also has a low flow resistance because it is relatively thin Wires 38 strung, which are, for example, about 15 mm apart.

The high DC voltage supplied is pulsating High voltage between about 2 to about 6 kV or higher. In the embodiment of the invention pulsating DC voltage between 1.6 and 3.2 kV is used, which is connected to a Frequency of 50 Hz pulsates.

Pulsating high DC voltage has the advantage that one in the same Way pulsating electric field is generated, which the air flowing through it and thus also stimulates the particles contained therein to vibrate and thereby the catching effect of the conductive fiber fleece is increased. For special applications it can be advantageous to adjust the operating frequency of the pulsating high DC voltage still to be increased, for example to a value between 100 and 1000 Hz.

The decisive advantages of the ultra-fine filter according to the invention over the prior art consist in the fact that there is little construction effort and downright modest energy costs about 99 to 99.5% of all that happen Securely filters out particles, while filters were already used in the prior art were considered excellent if they were 98% of all particles with a size of Filter out 0.3, mu and larger. The elimination of a restriction on this number of filters on certain particle sizes is important because about 50% of the Viruses, bacteria, microorganisms, etc.

are smaller than 0.3 / mu, the filter numbers of known filters so at all. not taken into account and therefore not filtered out in practice will.

Claims (16)

Expectations Id Electrostatic fine filter for gaseous media in which the Medium flowing through an electric field, characterized by a multitude of Individual cannulas running in the direction of flow, their flow-parallel boundary walls are at least partially formed by an electrically conductive fiber fleece (34), which is connected to one pole (26) of a high DC voltage source, whose Opposite pole on a metal grid (24) o. The like. Lies, which in turn in the flow direction is stretched in front of and across the individual channels (32, 34). 2. Fine filter according to claim 1, characterized in that a part the boundary walls (32) is metallic. 3. Fine filter according to claim 2, characterized in that the metallic Boundary walls consist of a corrugated sheet metal (32) that the fiber fleece (34) is plate-shaped is formed, and that the nonwoven fabric also between the wave crests of adjacent Corrugated sheet metal is clamped. 4. Fine filter according to claim 2 or 3, characterized in that the fiber fleece (34) wrapped in a meandering shape around adjacent corrugated sheet metal elements (32) is. 5. Fine filter according to at least one of the preceding claims, characterized marked that several Corrugated sheet metal elements (32) together with a web of nonwoven fabric (34) combined to form a fine filter assembly and are jointly connected to the high DC voltage source. 6. Fine filter according to claim 1 or 5, characterized in that at least two fine filter assemblies (10) one behind the other in the direction of gas flow are arranged. 7. Fine filter according to at least one of the preceding claims, characterized characterized in that the fiber fleece (34) or the fiber fleece web by means of an electrically conductive impregnation is electrically conductive. 8. Fine filter according to at least one of claims 1-5, characterized in that that in the direction of gas flow behind the last fine filter assembly (10) a single track made of fiber fleece and connected to the same electrical potential is like the assembly in front of it. 9. Fine filter according to claim 8, characterized in that the nonwoven web is mechanically supported by a grid element. 10. Fine filter according to at least one of the preceding claims, characterized characterized in that the electric field is generated by a pulsating high DC voltage source is produced. 11. Fine filter according to claim 10, characterized in that the pulse frequency is about 50 Hz. 12. Fine filter according to claim 10 or 11, characterized in that the high DC voltage has a value of about 1.6 kV to about 3.2 kV. 13. Fine filter according to claim 12, characterized in that in the; fiber fleece Glass particles are embedded. 14. Fine filter according to claim 13, characterized in that the glass particles have a grain size between about 0.3 to preferably 8 / mu. 15. Fine filter according to one of claims 2-14, characterized in that that the metallic boundary walls are formed by a sheet metal foil. 16. Fine filter according to one of claims 2-15, characterized in that that the metal sheets, foils or the like forming the metallic boundary walls. are bent in a zigzag shape in cross section and together with the Form fiber fleece (34) individual channels triangular in cross section.