DE102018201053A1 - Filter unit for air cleaning device - Google Patents

Abstract

The invention relates to a filter unit for an air cleaning device (1), comprising an ionization unit (22) and a separation unit (21) downstream of the ionization unit (22), the ionization unit (22) having an air inlet opening (200) and at least two Ionization components (220, 221, 222), of which at least one is an elongated ionization element (220) and at least one of a grounded electrode (221, 222). The filter unit (2) characterized in that the ionization components (220, 221, 222) in a surface direction (x, z) of the air inlet opening (200) are arranged distributed non-equidistantly. Furthermore, an air cleaning device (1) with such a filter unit (2) is described.

Description

The invention relates to a filter unit for an air cleaning device, in particular extractor hood.

In air cleaning devices, especially in fume hoods, which are operated in a kitchen, it is known to filter out liquid and solid impurities and odors from the steam and vapors produced during cooking. For this purpose, mechanical filters are usually used in the extractor hood. For example, expanded metal filters, perforated metal sheet filters, baffle filters, which can also be referred to as eddy current filters, edge suction filters and porous foam media are used as mechanical filters.

In addition, for example, in the DE 2146288 A an electrostatic precipitator is described. This has a plate-shaped deposition and counter electrodes existing deposition unit and an ionization unit, which has at least one wire-shaped ionization element, which can also be referred to as ionization, and at least two planar grounded plate-shaped counter electrodes, between which the ionization electrode is arranged. The ionization unit is connected upstream of the separation unit.

In this type of separator, the so-called corona discharge is used on the wire-shaped ionization electrode (spray wire). The corona is formed here between the spray wire and the grounded plate-shaped electrodes. The spray wire can be realized with a wire with a diameter <0.25 mm or with a so-called sawtooth geometry. The impurities present in the air stream, which are also referred to as particles, are charged as they flow through the volume between the grounded electrodes, in which the ionization electrode is arranged, and are subsequently deposited in the precipitator unit of the electrostatic precipitator.

A disadvantage of this deposition device is that the electric field which forms between the wire-shaped ionization unit and the plate-shaped electrode (s) is homogeneous over the volume and thus over the area of the air inlet opening. However, the flow conditions present at a deposition device are usually not homogeneous. Thus, either a high electric field must be generated, that is, a high ionizing current to be applied, or an insufficient particle deposition can be accepted.

It is therefore an object of the present invention to provide a filter unit, in particular an electrostatic precipitator, which is also referred to as electrostatic filter unit or electrostatic filter, in which, with a simple structure, an efficient charging of impurities contained in an air stream, which are also referred to as particles , and efficient deposition can be reliably ensured.

The invention is based on the finding that this object can be achieved by adapting the geometry of at least the ionization unit to the flow conditions.

According to the invention, the object is therefore achieved by a filter unit for an air cleaning device, comprising an ionization unit and a separation unit downstream of the ionization unit, wherein the ionization unit has an air inlet opening and at least two ionization components, of which at least one ionization component is an elongated ionization element and at least one Ionization component is a grounded electrode. The filter unit is characterized in that the ionization components are arranged distributed non-equidistantly in a surface direction of the air inlet opening.

The filter unit may also be referred to as a filter module, electrostatic precipitator or electrostatic filter unit. The filter unit preferably represents a removable from the air cleaning device, portable filter unit, which is preferably pre-assembled. As a pre-assembled filter unit is referred to, which can be installed as a structural unit in the air cleaning device and removed from this in one unit. As air cleaning device, a device is referred to, is sucked through the air, cleaned and returned. The air cleaning device may be, for example, an air conditioner, a room fan or, preferably, a fume hood, or, for example, an extractor hood, a ceiling fan, a desk ventilator, or a tray ventilation for use in a kitchen.

The filter unit comprises an ionization unit and a separation unit. The filter unit is arranged in the air cleaning device so that air is sucked through the filter unit via the fan of the air cleaning device. The filter unit is therefore preferably arranged in the region of the suction opening of the air purification device. The separation unit may have at least one precipitation electrode and at least one counterelectrode, which preferably each have a plate shape and preferably alternately parallel to one another in the separation unit are arranged. The separation unit is connected downstream of the ionization unit in the direction of flow of the filter unit, that is, the ionization unit flows through the air flowing through the filter unit.

The ionization unit has at least two ionization components. An ionization component here is an elongated ionization element and a further ionization component is a grounded electrode. The grounded electrode may also be referred to as the counter electrode of the ionization unit. The grounded electrodes preferably have a plate shape and are arranged parallel to each other. The ionization element, which may also be referred to as an ionization electrode, has an elongate shape, that is, a longitudinally extending component. The ionization element can be for example a wire or a sawtooth geometry and is also referred to as a spray electrode. Preferably, the ionization unit has at least two grounded electrodes and at least one ionization element and each ionization element is arranged between two grounded electrodes. An ionization element with its associated grounded electrodes is hereinafter also referred to as ionization zone. In an ionization zone, two ionization elements can also be arranged between two grounded electrodes assigned to these ionization elements.

The at least one ionization element is supplied with voltage, preferably high voltage, for example 7500V. As it flows through contaminated air, such as fumes and vapors, through the ionization unit, solid and liquid substances, also referred to as impurities or particles, are electrostatically charged by means of the ionization element, which may also be referred to as a spray electrode, and the at least one grounded electrode. In the separation stage, the particles thus charged are separated.

For the admission of air into the ionization unit, this has an air inlet opening, which may be formed, for example, on a housing in which the ionization components are arranged. The air inlet opening lies on the side of the ionization unit, which faces away from the separation unit. Air can enter the ionization unit and, for example, the interior of a housing via the air inlet opening. The housing may for example have a box shape. The bottom and the top wall of the housing and two side walls are preferably formed by air-impermeable material. The front and back of the housing, however, are open or formed by an air-permeable component, in particular a grid.

For ease of reference to the dimensions of the filter unit becomes a right-handed Cartesian xyz Coordinate system introduced in which the three mutually perpendicular coordinate axes x . y . z span the space of the filter unit. By the of the x - and z -Axes spanned xz Plane is an area in which the air inlet opening of the ionization unit and thus the air inlet opening of the filter unit is located. The xz Level is preferably in the installed state of the filter unit in the air purification device in the vertical. The dimension of the filter unit in the x- Direction is called width. The dimension of the filter unit in the z Direction is called height. The y -Axis points in the flow direction of the air flow entering through the air inlet opening. The xy Level is in the installed state of the filter unit in the air purification device preferably in the horizontal. Particularly preferably, the ionization components each extend in the xy Plane, that is vertically. The ionization element extends in the width direction of the air inlet opening. The dimension of the filter unit in the y Direction is called depth. Hereinafter, instead of referring to the coordinate system, reference will also be made to the horizontal and vertical or to the width, height and depth to describe the location and extent of the filter unit and parts thereof.

According to the invention, the ionization components are arranged distributed non-equidistantly in a surface direction of the air inlet opening. The surface direction in which this distribution is present is preferably the z Direction, that is, the height direction of the air inlet opening. Depending on the embodiment of the air cleaning device in which the filter unit is to be used, the surface direction but also the x -Direction, that is to say the width of the air inlet opening. Non-equidistant is a distribution of the ionization components in the surface direction in which the ionization components lie closer to one another in one region than in at least one further region of the surface direction.

By the ionization components and in particular an ionization element and at least one grounded electrode are closer to each other, an electric field will be generated in this area, which has a higher field strength. As a result, the sufficient charge can also be ensured by larger particles or particles which flow through this region at a higher flow velocity. In addition to the nature of the electric field are namely also the speed and the volume of the particles are crucial. The slower a particle is when flowing through the ionization unit, the more efficient is its charge. The smaller the volume of the particles, the more efficiently the charge required for successful deposition is achieved. Due to the sufficient charge can thus be ensured the reliable deposition in the downstream separation unit. In the case of non-equidistant arrangement of the ionization components in an ionization zone, it is not necessary to apply a higher ionization current in this region. With the reduction of the necessary ionization current also a reduction of the ozone formation is achieved.

According to one embodiment, the ionization unit has as ionization components at least one ionization element and two grounded electrodes assigned to this ionization element, a first distance in a surface direction of the air inlet opening and between the ionization element and the second exists between the at least one ionization element and a first of the grounded electrodes assigned to this ionization element the earthed electrode associated with this ionization element is a second distance in the surface direction and the first distance is smaller than the second distance.

Grounded electrodes associated with an ionization element are referred to as grounded electrodes, between which the ionization element is disposed. The grounded electrodes are preferably planar plates. First and second distances, respectively, are the distance between one of the grounded electrodes and the ionization element in the direction perpendicular to the surface of the grounded electrode. The terms "first" and "second" are only for better distinction. The ionization element is thus arranged eccentrically between the grounded electrodes. In this embodiment, the non-equidistant distribution of the ionization components thus lies between the ionization element and the grounded electrodes. Since the first distance is smaller than the second distance, the electric field generated between the grounded electrodes around the ionization element is not homogeneous, but larger in the range of the first distance. This embodiment can be used, for example, in a filter unit in which the ionization unit has as ionization components only one ionization element and two earthed electrodes associated therewith. In this embodiment, the ionization unit consists of a single ionization zone.

According to a further embodiment, the ionization unit has as ionization components at least two ionization elements and at least three grounded electrodes, of which two grounded electrodes are assigned to one ionization element, and a first distance which lies between two adjacent electrodes in a surface direction of the air inlet opening is smaller than the second distance, which lies between two further adjacent electrodes in the surface direction of the air inlet opening.

In this embodiment, an electric field is generated between each of the ionization elements and the respective associated grounded electrodes. An ionization element with its associated grounded electrodes is also referred to as ionization zone. Since in this embodiment a plurality of ionization elements with associated grounded electrodes are provided, the ionization unit in this case has a plurality of ionization zones. In this case, the distance between adjacent grounded electrodes is understood to mean the distance between these electrodes perpendicular to their surface, in which the respective ionization element is arranged. If three grounded electrodes are provided, the ionization unit has two ionization zones and the first distance lies between a first grounded electrode and a second electrode adjacent thereto and the second distance lies between the second and a third electrodes adjacent thereto. The second electrode is part of the two ionization zones. The terms "first", "second" and "third" are only for better distinction. Since a first distance is smaller than a second distance, that is, two grounded electrodes are closer to each other than two further earthed electrodes, the electric field in the surface direction of the air inlet direction, in which the distances lie, in particular in height, is not homogeneous and can thus be adapted to the flow conditions. In particular, the ionization zone can be arranged with a higher electric field, that is, with a greater electric field strength in the region in which larger particles or particles flow at a higher speed.

According to an embodiment, at least one ionization element has the same distance to each of the two grounded electrodes associated with that ionization element in a plane direction of the air inlet opening.

In an embodiment in which at least two ionization zones are formed and the distance between the grounded electrodes is smaller in at least one ionization zone than in a further ionization zone, therefore, the ionization elements can be arranged in the ionization zones such that they are each centered in the distance between the grounded ones Electrodes are located. It is also true this embodiment in the context of the invention that at least one of the ionization elements is located eccentrically between the grounded electrodes.

According to an embodiment, the distance between two adjacent grounded electrodes is equal to the distance between two further adjacent electrodes in the plane direction of the air inlet opening. This means that the distances of at least two ionization zones are the same. In this embodiment, the ionization element is then preferably arranged eccentrically between the grounded electrodes in at least one ionization zone.

According to one embodiment, the first distance or the first distance lies in an end region of the surface direction of the air inlet opening. This means that in the end region of the surface direction, for example in the upper region of the height direction, the distance between grounded electrodes of an ionization zone is less than the distance in underlying ionization zones. Alternatively or additionally, in the end region, for example the upper region of the height direction, the distance between the ionization element and a grounded electrode may be small, as the underlying second distance to the second grounded electrode of the same ionization zone. As a result, a higher electric field is generated in the upper area of the surface direction, thereby achieving an increased charge of the particles. This embodiment is advantageous, for example, in a filter unit which is installed in an air cleaning device such that the air inlet opening lies in the vertical and the air cleaning device is flown from below, that is parallel to the air inlet opening, by fumes and vapors. Because of this direction of flow, namely the flow velocity in the upper region of the air inlet opening of the filter unit will be greater. In addition, due to the inertia of the contaminant particles in the upper portion of the air inlet opening, larger particles will enter the filter unit. Thus, the better charging in the upper region in this arrangement of the filter unit is advantageous.

According to a further embodiment, the first distance or the first distance lies in a central region of the surface direction of the air inlet opening. In this embodiment, the best charge of the particles is thereby achieved in the central region of the surface direction, for example the height. This embodiment can therefore be used advantageously in air cleaning devices in which the filter unit is introduced so that it is flowed from the side, that is perpendicular to the air inlet opening.

According to a further embodiment, the filter unit has at least three ionization elements and at least four grounded electrodes, of which in each case two grounded electrodes are assigned to a common ionization element. In this embodiment, the filter unit thus has at least three ionization zones. The difference between the distances between adjacent grounded electrodes, that is to say the difference between the distances in the ionization zones, can in this case continuously decrease and / or increase over the area direction of the air inlet opening. Thus, for example, in the height direction, an ionization zone with a greater distance between the grounded electrodes, followed by an ionization zone with a smaller distance between the grounded electrodes and, subsequently, an ionization zone with a greater distance between the grounded electrodes can be present. However, it is also within the scope of the invention that a plurality of ionization zones lie one above the other at the same distance in the vertical direction and only the upper or a plurality of upper ionization zones have shorter distances.

According to a further embodiment, the deposition unit comprises at least two precipitation electrodes and at least two counterelectrodes, and the arrangement of precipitation and counterelectrodes is non-equidistant in a plane direction of the air inlet opening. In particular, in a region in which the flow velocity of the air flowing through the separation unit is greater, the precipitation electrodes and counterelectrodes may be closer to one another, for example in the upper region, than in the further region of the precipitation unit. In this way, in addition to the increased charge of the impurity particles in the ionization unit, a more reliable deposition in the separation unit can be achieved.

The at least one smaller distance or the at least one smaller distance between ionization components is preferably in the region of the plane direction of the air inlet opening in which the flow velocity of the air flowing through the filter unit is greatest and / or the particle size of the air flowing through is greatest.

Thus, the design of the air cleaning device in which the filter unit is used, be taken into account. In the case of air purification devices, in particular extractor hoods, there is generally a deflection of the air flow shortly before the ionization unit or behind the ionization unit or the separation unit. By this deflection, the velocity profile of the flowing medium has a non-homogeneous Distribution on. Due to the deflection of the air flow and the associated inertial effects also exists a non-homogeneous distribution of the particle size. By arranging the ionization zones with less distance or less distance in this area, good charging and deposition can nevertheless be achieved in these areas.

The surface direction of the air inlet opening over which the ionization components are arranged non-equidistant, for example, the height direction of the air inlet opening. However, it is also within the scope of the invention that the surface direction is, for example, the width of the air inlet opening. This embodiment can be used, for example, in air cleaning devices in which the suction opening of the air cleaning device is laterally offset from the air inlet opening.

The grounded electrodes of the ionization unit are preferably planar plates. The ionization element may be a wire or a spray electrode with a sawtooth geometry.

Furthermore, the invention relates to an air purification device having at least one filter unit according to the invention.

Features and advantages that are described with respect to the filter unit according to the invention apply - as far as applicable - also for the air cleaning device and vice versa and are therefore possibly described only once.

• 1: eine schematische Perspektivansicht einer Ausführungsform der erfindungsgemäßen Luftreinigungsvorrichtung;
• 2: eine schematische Schnittansicht einer Ausführungsform der erfindungsgemäßen Luftreinigungsvorrichtung;
• 3: eine perspektivische Teilschnittansicht einer Ausführungsform der erfindungsgemäßen Filtereinheit;
• 4: eine schematische Prinzipskizze einer weiteren Ausführungsform der erfindungsgemäßen Filtereinheit; und
• 5 bis 7: schematische Prinzipskizzen von Ausführungsformen der Ionisationseinheit der erfindungsgemäßen Filtereinheit.

The invention will be described again below with reference to the accompanying drawings. Show it:

• 1 a schematic perspective view of an embodiment of the air cleaning device according to the invention;
• 2 a schematic sectional view of an embodiment of the air cleaning device according to the invention;
• 3 FIG. 2: a perspective partial sectional view of an embodiment of the filter unit according to the invention; FIG.
• 4 FIG. 2 is a schematic diagram of a further embodiment of the filter unit according to the invention; FIG. and
• 5 to 7 : schematic schematic diagrams of embodiments of the ionization unit of the filter unit according to the invention.

In 1 is an embodiment of an air cleaning device according to the invention 1 , which may also be referred to as a fume extractor or hood. The air purification device 1 has a fume hood housing in the illustrated embodiment 10 and one below, ie in the flow direction from the bottom of the extractor housing 10 lying baffle plate on. Between the bottom of the extractor housing 10 and the baffle plate is a suction gap, which can also be referred to as Einsaugspalt or suction of the air cleaning device is formed. In the suction gap are several filter units 2 brought in. In the illustrated view are across the width of the air cleaning device 1 two filter units 2 and about the depth of the air purification device 1 two filter units 2 brought in. From the filter units 2 is in the 1 only the air inlet opening 200 , which is covered by a protective grid and the front sides of the filter units 2 form, recognize.

In 2 is a schematic sectional view of the embodiments of the air purification device 1 according to 1 shown. As it turned out 2 results, includes each filter unit 2 an ionization unit 22 and a separation unit 21 , The ionization unit 22 lies in the flow direction in front of the separation unit 21 , In the extractor housing 10 is a fan 11 arranged, which generates a negative pressure, by means of which the air in the extractor housing 10 is sucked in. The air passes through the air inlet opening 200 into the ionization unit 22 a, then happens the separation unit 21 and leaves the filter unit 2 to go to the blower 11 to get. About an unillustrated air outlet, the thus purified air from the air purification device 1 be delivered. To enter the air inlet 200 To be able to enter, must be the inflowing air stream from below L be redirected. Also at the exit from the separation unit 21 there is a deflection of the air flow L towards the blower 11 , By this deflection, the velocity profile of the air flow L a non-homogeneous distribution. In particular in the upper region of the air inlet opening 200 the air flows into the filter unit at a higher flow rate 2 on. Due to the deflection of the air flow at the air inlet opening 100 and the associated inertia effects, there is also a non-homogeneous distribution of particle sizes.

In 3 is a schematic partial sectional view of an embodiment of a filter unit according to the invention 2 shown. In the 3 In addition, the right-handed Cartesian coordinate system is schematically indicated. In the xz -Axis is the front of the filter unit 2 , The filter unit 2 has a housing in the illustrated embodiment 20 , in the front of which the air inlet opening 200 the filter unit 2 is formed. In the illustrated embodiment, the air inlet opening 200 covered by a grid. In the case 20 is in the front area the ionization unit 22 and in the rear area the separation unit 21 educated. The ionization unit 22 In the illustrated embodiment, it comprises three ionization components. These ionization components are an ionization element 220 and two grounded electrodes 221 . 222 , The earthed electrodes 221 . 222 In the illustrated embodiment, elongated plates are shown extending across the width of the filter unit 2 , that is in the x-direction, extend. The first grounded electrode 221 lies here in the case 20 below and the second electrode 222 above. The earthed electrodes 221 . 222 lie parallel to each other. Between the grounded electrodes 221 . 222 is the ionization element 220 , The ionization element 220 This represents an ionization wire and extends parallel to the grounded electrodes 221 . 222 , The earthed electrodes 221 . 222 form together with the ionization element 220 an ionization zone 223 out.

The ionization element 220 is to the grounded electrodes 221 . 222 arranged off-center and offset in the illustrated embodiment upwards. In particular, the arrangement of the ionisationselementes 220 in the plane direction of the air inlet opening 200 in the Z -Axis lies, that is in height, non-equidistant. Due to the smaller distance a between the ionization element 220 and the upper grounded electrode 222 In this area, a higher electric field is generated.

The separation unit 21 consists in the illustrated embodiment of plate-shaped collecting electrodes 211 and plate-shaped counter electrodes 211 which are aligned parallel to each other. The precipitation electrodes 211 and counter electrodes 210 are arranged alternately and extend in the plane Y Z that is, are vertically aligned and perpendicular to the ionization components.

In 4 is a schematic schematic diagram of another embodiment of a filter unit 2 shown. This embodiment differs from that in FIG 3 shown embodiment in that the counterelectrodes 210 and precipitation electrodes 211 lying in the horizontal. This means that the collecting electrodes 211 and counter electrodes 210 in the XY Layers lie. The ionization unit 21 has the in the 3 shown construction. In addition, in the 4 the velocity distribution of the incoming air L shown schematically. In the area of the smaller distance a between the ionization element 120 and the upper grounded electrode 222 the flow velocity is higher than at the lower distance A between the ionization element 220 and the lower grounded electrode 221 , The contaminant particles that are carried in the air stream can therefore be in the upper part of the ionization unit 22 be charged reliably despite the high flow rate. In the embodiment according to 4 are also the precipitation electrodes 211 and counter electrodes 210 arranged non-equidistantly to each other. In particular, the distance between adjacent collecting electrodes 211 and counter electrodes 210 in the upper part of the separation unit 21 less than the lower range. In this way, despite the higher flow velocity of the air and possibly larger particle sizes, a reliable deposition in the separation unit 21 be guaranteed.

In the 5 to 7 are other embodiments of the ionization unit 22 shown schematically. In the embodiment according to 5 includes the ionization unit 22 three ionization zones 223 , At the lower ionization zone 223 is the ionization element 220 between the lower grounded electrode 221 and an upper grounded electrode 222 arranged. The upper grounded electrode 222 the lower ionization zone 223 simultaneously forms the lower grounded electrode 221 the overlying ionization zone 223 , The same applies to this ionization zone 223 and the overlying upper ionization zone 223 ,

The distance of the earthed electrodes 221 . 222 each ionization zone 223 , hereinafter referred to as distance, is in the single ionization zone 223 differently. In the upper ionization zone 223 is distance d lower than in the underlying further ionization zone 223 , In addition, the middle ionization zone 223 a smaller distance D on, as the lower ionization zone 223 , Already by this arrangement of grounded electrodes 221 . 222 is at the top of the ionization unit 22 ensures a better charging of impurity particles. In the embodiment according to 5 are the distances A between the ionization element 220 and the associated grounded electrodes 221 . 222 in the respective ionization zone 223 equal. This means that the ionization element 220 in the respective ionization zone 223 is centrally located.

The embodiment according to 6 differs from the embodiment according to 5 in that the ionization zone 223 with a smaller distance d between ionization zones 223 with greater distance D is arranged. This design of the ionization unit 22 can thus with air purification devices 1 be used, where the airfoil in the middle of the height of the air inlet opening 200 has the highest speed.

The embodiment according to 7 differs from the embodiment according to 5 in that in addition to the smaller distance d in the upper ionization zone 223 also the ionization element 220 in this ionization zone in the height direction is arranged except in the middle. In particular, the distance a between the upper grounded electrode 222 and the ionization element 220 less than the distance A between the ionization element 220 and the lower grounded electrode 222 the upper ionization zone 223 ,

In an eccentric arrangement of the ionization element to associated grounded electrodes, a higher field can be achieved in regions of higher flow rate. In addition, tuning the distribution of the particle size can be achieved by shaping the electric field. In the case of the deflection of the air flow, the larger particles are, for example, in the outer or upper region. A shift of the ionization element towards this area accordingly also leads to a better charging of the particles. When using an ionization unit with multiple ionization zones, a non-uniform distribution and geometry of the ionization zones can be used. In this case, the distance between the plates, that is to say the distance between the grounded electrodes of a plurality of ionization zones connected in parallel, can be adapted to the velocity profile or the distribution of the particle size.

The present invention has a number of advantages. In particular, a more efficient charging of contaminated particles, in particular fat and other liquid particles, can be ensured. In this case, despite an inhomogeneous distribution over the cross section of the particle size and the particle velocity, the efficiency of the charge can be increased. In addition, the ozone formation and the ionizing current can be reduced. In order to ensure complete charging of all particles, in the prior art, the ionization current must be dimensioned so that the largest and fastest particles are charged. By adapting the ionization geometry of the filter unit according to the invention to the flow rate and particle size, the ionization current can be chosen as small as possible. The reduction of the ionization current is thus accompanied by the reduction of ozone formation.

LIST OF REFERENCE NUMBERS

1

Air cleaner

10

Extractor housing

11

fan

2

filter unit

20

casing

200

Air inlet opening

21

separation unit

210

counter electrode

211

Collecting electrode

22

ionization

220

Ionisationselement

221

grounded electrode

222

grounded electrode

223

ionization region

3

stove

L

airflow

A

distance

a

less distance

D

distance

d

shorter distance

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 2146288 A [0003]

Claims (13)

Filter unit for an air purification device (1), comprising an ionization unit (22) and a separation unit (21) which is downstream of the ionization unit (22), the ionization unit (22) having an air inlet opening (200) and at least two ionization components (220, 220). 221, 222), of which at least one is an elongated ionization element (220) and at least one grounded electrode (221, 222), characterized in that the ionization components (220, 221, 222) are arranged in a surface direction (x, z) the air inlet opening (200) are arranged distributed non-equidistantly. Filter unit after Claim 1 , characterized in that the ionization unit (22) has as ionization components (220, 221, 222) at least one ionization element (220) and two grounded electrodes (221, 222) assigned to this at least one ionization element (220), between an ionization element (220). and a first of said grounded electrodes (221, 222) associated with said ionization element (220) has a first distance (a) in a surface direction (x, z) of said air inlet port (200) and between said ionization element (220) and said second ionization element (220) associated grounded electrodes (222, 221) a second distance (A) in the surface direction (x, z) of the air inlet opening (200) and the first distance (a) is smaller than the second distance (A). Filter unit according to one of Claims 1 or 2 , characterized in that the ionization unit (22) as Ionisationskomponenten (220, 221, 222) at least two ionization elements (220) and at least three grounded electrodes (221, 222), of which two grounded electrodes (221, 222) an ionization element (220), and a first distance (d) lying between two adjacent electrodes (221, 222) in a plane direction (x, z) of the air inlet port (200) is smaller than a second distance (D) between two further adjacent electrodes (221, 222) in the surface direction (x, z) of the air inlet opening (200). Filter unit according to one of Claims 1 to 3 characterized in that at least one ionization element (220) to each of the two grounded electrodes (221, 222) associated with that ionization element (220) in a face direction (x, z) of the air inlet port (200) is the same distance (A ) having. Filter unit according to one of Claims 1 to 4 characterized in that the distance (D) between two adjacent grounded electrodes (221, 222) is equal to the distance (D) between two further adjacent electrodes (221, 222) in the surface direction (x, z) of the air inlet port (200 ). Filter unit according to one of Claims 1 to 5 , characterized in that the first distance (d) or the first distance (a) in an end region of the surface direction (x, z) of the air inlet opening (200). Filter unit according to one of Claims 1 to 6 , characterized in that the first distance (d) or the first distance (a) in a central region of the surface direction (x, z) of the air inlet opening (200). Filter unit according to one of Claims 3 to 7 , characterized in that the filter unit (2) has at least three ionization elements (220) and at least four grounded electrodes (221, 222), of which in each case two grounded electrodes (221, 222) are associated with an ionization element (220), and the difference between the distances (d, D) between adjacent grounded electrodes (221, 222) decreases and / or increases continuously over the surface direction (x, z) of the air inlet opening (200). Filter unit according to one of Claims 1 to 8th , characterized in that the deposition unit (21) comprises at least two precipitation electrodes (211) and at least two counterelectrodes (210) and the arrangement of the precipitation electrodes (211) and counterelectrodes (210) in a surface direction (x, z) of the air inlet opening (200) non-equidistant. Filter unit according to one of Claims 1 to 9 , characterized in that the at least one smaller distance (a) or the at least one smaller distance (d) between ionization components (220, 221, 222) lies in the area of the surface direction (x, z) of the air inlet opening (200) the flow velocity of the air flowing through the filter unit (2) is greatest and / or the particle size is the largest in the air flowing through. Filter unit according to one of Claims 1 to 10 , characterized in that the surface direction (x, z) is the height of the air inlet opening (200). Filter unit according to one of Claims 1 to 11 characterized in that the grounded electrodes (221, 222) are planar plates and the ionization element (220) is a saw toothed wire or discharge electrode. Air purification device with at least one filter unit (2), characterized in that the Filter unit (2) a filter unit (2) according to one of Claims 1 to 12 is.

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