SE455170B - ELECTROFILTER Condenser Separator - Google Patents

Abstract

An electrostatic precipitator intended for use with electrofilters comprises a plurality of electrically conductive or semi-conductive plate-like or lamella-like precipitation electrodes (1, 2) which are arranged in mutually parallel spaced relationship. The electrodes (1, 2) are connected alternately to the one and the other terminal of a d.c. voltage source (3) by bringing an edge-surface part of those electrodes which are connected to one and the same terminal into pressure-contact with one side of a sheet-like or strip-like member (4 or 5) which is made of a highly resistive, antistatic material. The opposite side of the member (4, 5) has provided thereon an electric contact means (6 or 7) which is connected electrically to the relevant terminal of the d.c. voltage source (3), preferably through a high ohmic resistance (8 or 9).

Description

15 20 25 30 OG (ru 455 170 2 In order for such a capacitor separator to have a high efficiency, ie the ability to safely separate a large proportion of the pollutants in the flowing air, a high field strength between adjacent precipitating elements is required, ie. However, in the hitherto known configurations of capacitor separators, there are considerable difficulties in fulfilling these requirements.

In these known capacitor separators, small distances and high voltages between adjacent precipitation elements entail an unacceptably high risk of glow charges from the precipitation elements, which glow charges occur in particular at the edges of the usually thin sheet metal precipitating elements. these edges are sharp or uneven as a result of the manufacturing method of the precipitating elements, and are further aggravated by the unavoidable soiling of the precipitating elements during the use of the capacitor separator. Such glow discharges give rise to a very disturbing noise (crackling or crackling) and further cause an undesirable and in many cases unacceptable production of ozone. It is further understood that the precipitating elements must in some way be held in place with the desired mutual distance. If this is done by means of spacers of electrically insulating material arranged between the precipitating elements, these spacers will inevitably be soiled during the use of the capacitor separator; wherein creeping currents occur on the soiled surface of the spacer elements, which creep currents eventually destroy the insulating material in the spacer element, unless the insulating material is of very high quality. In known capacitor separators, therefore, relatively complicated and thus expensive constructions are usually used in order to eliminate as far as possible the need for electrically insulating spacers with short creepage current distances. It will also be appreciated that a capacitor separator will exhibit significant capacitance. An unintentional touch of the precipitating element of the capacitor separator therefore gives rise to a strong capacitive discharge current, which is very unpleasant and can even be directly dangerous. In the case of electric filters intended for use in a humane environment, for example in homes or work premises, care must therefore be taken that the capacitor separator cannot be accidentally touched. This entails requirements for the design of the electrostatic precipitator, which often run counter to other requirements, such as small dimensions, low airflow resistance, etc. The object of the present invention is therefore to provide a capacitor separator of the type indicated initially, in which the difficulties discussed above are overcome. , so that higher voltages and smaller distances can be used between adjacent precipitation elements, whereby a significantly more efficient separation of the charged aerosol-shaped contaminants in the air flowing through the capacitor separator is achieved.

According to the invention, this is achieved with a capacitor separator of the type indicated in the introduction, in that at least the precipitation elements connected to one pole of the direct voltage source are not, as hitherto usual, directly electrically connected to each other and to the pole of the direct voltage source but instead is individual, ie. individually, connected to the pole of the DC voltage source by being arranged to have an edge portion thereof pressed against one side of a sheet, sheet or strip-shaped piece of a highly resistive material, which material thickness is provided with one of the precipitation elements contact points with the piece of material separate electrical contacting, which is electrically connected to the pole in question of the direct voltage source. Advantageously, the precipitating elements connected to the second pole of the direct voltage source are also connected in the same way. Usually, one pole of the high voltage source is electrically grounded, the precipitating elements connected to the high voltage pole connected thereto being connected to the direct voltage source individually and separately in the manner indicated.

Said material with very high resistivity is advantageously constituted by a highly resistive, so-called antistatic or antistatic treated plastic material, for example of the type often used for packaging semiconductor components to protect them against electrostatic voltages. Such antistatic or antistatic treated plastic materials are generally available on the market and have a surface resistivity usually in the range 109-10159 and usually of the order of 10130.

By means of the invention it is achieved that at least the precipitating elements connected to one pole of the direct voltage source, namely its non-earthed high voltage pole, are electrically connected to the pole of the direct voltage source as well as to each other by very high resistances. This means that the currents which can occur as a result of discharges from the precipitating elements or as a result of creeping currents along electrically insulating spacer elements between precipitating elements with different voltages are limited to extremely small values, for example of the order of 10-100 nA, whereby said discharges become so small and insignificant, that they do not give rise to any audible sound or any troublesome ozone generation, and the possible creep currents become so small that they have no detrimental effect on the insulation material. In the case of a capacitor separator according to the invention, in fact each precipitation element will automatically, as a result of very modest discharges and / or very small creeping currents with existing electrically insulating spacer elements, set itself to an individual voltage level. Not even a direct short circuit between two nearby precipitating elements will cause any dangerous short-circuit currents and will not affect the voltage level of other precipitating elements, so the capacitor separator can continue to operate practically unaffected. Furthermore, the invention eliminates the possibility of strong capacitive discharge currents in the event of contact with the precipitating elements, so that the risks or inconveniences of such an unintentional contact with the precipitating element of the capacitor separator are eliminated.

In the following, the invention will be described in more detail in connection with the accompanying drawing, which as an example illustrates an advantageous embodiment of a capacitor separator according to the invention.

The drawing shows the capacitor separator only schematically, seen in the direction of the air flow through the capacitor separator and with the air flow channel surrounding the capacitor separator omitted for the sake of simplicity and clarity.

The capacitor separator consists of a plurality of lamella- or disc-shaped precipitating elements 1 and 2, which are arranged parallel next to and at a mutual distance from each other with their side surfaces parallel to the direction of the air flow, i.e. perpendicular to the plane of the drawing. These precipitating elements are electrically conductive or semiconductive. It should be noted in this connection that the currents to be conducted by the precipitating elements are very small, since they correspond only to the charge of the pollutants which precipitate on the elements and to the air ions which may discharge at the elements.

The precipitating elements 1, 2 can thus admittedly consist of metal, but can also consist of other weakly conductive or semiconducting material, such as for example semiconducting paper or cardboard. The precipitating elements 1, 2 are alternately electrically connected to each pole of a direct voltage source 3. In the advantageous embodiment of a capacitor separator according to the invention shown as an example, this connection of the precipitating elements 1, 2 to the two poles of the direct voltage source 3 is provided. in that the precipitating elements 1, 2 have their one side edges or at least parts of these side edges pressed or pressed against one side of a disc, sheet or strip-shaped piece H resp. 5 of a highly resistive, so-called antistatic or antistatic treated plastic material. Such antistatic or antistatic treated plastic materials are well known per se and were used i.a. for packaging semi-conductors to protect them against electrostatic voltages during transport and storage. These plastic materials have a surface resistivity in the range 109-10159 and usually of the order of 10139. An antistatic plastic material of this kind which has been found to be well useful in the invention is the material marketed under the name MPAC by MAGNAB, Nyköping, Sweden. The plastic pieces H, 5 can have a thickness of, for example, 1-5 mm and are somewhat resilient or elastic, so that the side edges of the precipitating elements 1,2 can be kept in good abutment against one side surface of the plastic pieces by means of a suitably adapted pressure. The opposite side surfaces of the plastic pieces 4,5 are provided with an electrical contact 6 resp. 7, for example in the form of a wire, strip, plate or the like of metal which is kept pressed against the surface of the plastic piece, and this pressure contact 6 resp. 7 is electrically connected to the pole of the direct voltage source 3, suitably by a high-resistance resistor 8 resp. 9.

The relatively soft and resilient pieces H, 5 of antistatic plastic material can advantageously be arranged in rigid holders 10 resp. ll of a well insulating plastic material.

By the arrangement according to the invention it is achieved that each precipitating element 1, 2 is individually electrically connected to the associated pole of the direct voltage source 3 by a very large resistance formed by the antistatic plastic piece H and 5, respectively. Such a large resistance is not only between the precipitating elements 1 , 2 and associated poles of the direct voltage source 3 but also mutually between the different precipitation elements 1 resp. 2, which are connected to the same pole of the direct voltage source 3. As a result, the discharges which may occur at the edges of the precipitation elements 1, 2 will be limited to such an extent that they become completely inaudible and do not give rise to any appreciable ozone generation. In the same way, any creep currents along existing, electrically insulating spacer elements between the precipitation elements 1 and 2 will be limited to such values that the insulation material is not affected by the creep currents. Likewise, only very small short-circuit currents will be able to occur in the event of a direct short-circuit between two adjacent precipitating elements 1 and 2, respectively. In reality, each individual precipitating element 1, 2 will automatically set themselves to a voltage level, which is dependent on existing discharge currents, creep currents and short-circuit currents through the precipitation element in question. A lowering of the voltage level of a certain precipitating element will not affect the voltage levels of the other precipitating elements and will therefore not significantly affect the function and efficiency of the capacitor separator in general.

The arrangement according to the invention also means that no large, dangerous or unpleasant, capacitive discharge currents can occur in the event of an unintentional touch of the precipitating elements 1, 2.

The task of the high-ohmic resistors 8, 9 is above all to prevent large short-circuit currents, should any of the plastic pieces U, 5 be directly short-circuited, for example by an unintentional water spray.

Usually one pole of the direct voltage source 3 is earthed, as shown in the drawing, it being conceivable in a capacitor separator according to the invention to connect this earthed pole of the direct voltage source 3 directly in a conventional manner to the corresponding precipitating element 2. However, it is also in such a case to prefer to also connect the grounded pole of the direct voltage source 3 to the associated precipitating elements 2 by means of a highly resistive, antistatic or antistatic treated piece of plastic 5, as shown in the drawing.

Advantageously, the precipitating elements 1, 2 are arranged at a capacitor separator with the construction shown in the drawing in such a way that the distance between the plastic piece U and the precipitating elements 2 not connected thereto is greater than the mutual distance between precipitating elements 1 and 2. correspondingly, the distance between the plastic piece 5 and the precipitating elements 1 not connected thereto is greater than the mutual distance between adjacent precipitating elements 1 and 2. This prevents direct overlap between the precipitating elements 2 and the plastic piece H and between the precipitating elements 1, respectively. and the plastic piece 5.

The precipitating elements 1, 2 are held in place and at the desired distance from each other by means of no further in the drawing. shown spacer elements of electrically insulating material. There is a great deal of freedom in this regard with regard to the design and placement of these spacer elements as well as with regard to the choice of insulating material therein, since any creeping currents along the spacer elements become very small and thus harmless, as described above. Thus, these spacer elements may, for example, consist of a suitable castable, electrically insulating resin or glue, which is applied in suitable places between the precipitation elements 1, 2.

Because the precipitating elements 1, 2 can be manufactured, for example, from semiconductor paper or cardboard, a capacitor separator according to the invention can be manufactured in a very simple and inexpensive manner, so that it can be intended for single use, ie. the entire capacitor separator or at least the part formed by the precipitating elements 1, 2 is discarded and replaced with a new unit, as the old one has become too heavily soiled.

Claims (7)

* l 455 170 Patent claim 1. Capacitor separators for electrostatic precipitators, comprising a plurality of disk- or lamella-shaped, electrically conductive or semiconductive precipitating elements (1, 2), which are arranged parallel next to and at a mutual distance from each other, and these precipitating elements are alternately electrically connected to one pole and the other pole, respectively, of a direct voltage source (3), characterized in that at least the precipitating elements (1 or 2) connected to one pole of the direct voltage source (3) are individually connected to said pole by being arranged having an edge portion with it pressed against one side of a sheet, sheet or strip-shaped piece (4 or 5) of a highly resistive material, which piece of material is provided with an electrical contact with the piece of material separate from the contact points of the precipitating elements ( 6 and 7), respectively, which is electrically connected to the pole of the DC voltage source (3). Device according to Claim 1, characterized in that all the precipitation elements (1, 2) are individually connected to the respective pole of the direct voltage source (3) in the manner indicated. 3. Device according to claim 1 or 2, characterized in that the highly resistive material (H, 5) consists of an antistatic plastic material with a surface resistivity in the range 109-10159 and preferably of about 10139. Device according to claim 1, characterized in that the pole of the direct voltage source (3) is electrically connected to the contact ring (6 or 7) on the piece of material (H or 5) by a high-resistance resistor (8 or 9). Device according to claim 1, characterized in that said piece of material (U, 5) is somewhat elastic or resilient. G. Device according to any one of claims 1 - 5, characterized in that the precipitating elements (1, 2) are held in place with each other by means of spacer elements of electrically insulating material. 455 170 40 Device according to claim 6, characterized in that said spacer elements are formed of a castable, electrically insulating plastic material or glue.