PROCEDURE, FILTER MODULE, AIR CLEANING DEVICE COMPOSED OF SUCH FILTER MODULES FOR THE HIGHLY EFFICIENT CLEANING OF AIR CONTAINING SMALL CONTAMINATING PARTICLES

Abstract

The subject of the invention is a procedure, a filter module, and an air cleaning device composed of such filter modules for the highly efficient cleaning of air containing small contaminating particles. In the course of the procedure, the principle of adhesion and repelling effect is exploited to capture the contaminating particles in the device composed of an appropriate number of filter modules (1). The air to be cleaned is moved like a quasi-electrodynamic linear engine in the device, so that the mass and/or size of the coagulated particles is increased by the powers of two as necessary while passing through two sequential filter modules (1), up to 2.sup.20 value. This way, the flow velocity of the fine grains with increased mass is decreasing gradually and they are separated or fall out from the flow space, meaning that particles with a starting size below 1 micrometre, in the nano-range, which are the most harmful to the human body, may also be captured. The essential part of the invention is the filter module (1) that is fitted with electrodes (7), composed of a collector (5) and a separator (6) located at a given distance, which are connected to a positive or negative high voltage (8, 9) and are surrounded by a cover consisting of a base plate, connected to zero potential (10), side plates, and a cover plate. Two electrodes (7) form an electrode pair, and two electrode pairs form a filter module (1), where the electrode pairs are placed so that there is one electrode (7) of the opposite potential installed between two electrodes (7) of the same potential. The solution according to the invention may be used in versatile ways, especially on the field of civil environmental protection, as stand-alone, pre-, or post-filter, such as for cleaning the air and exhaust gas in the chimney of industrial plants, for cleaning polluted urban air, for cleaning, de-germination, and filtering pollen from the air of closed premises, and for military purposes on the field of NBC safety as a pre-filter.

Claims

1. A method for the cleaning of air containing small-sized contaminating particles with high efficiency, so that the air to be cleaned is channeled to a device composed of one or more filter modules (1), each comprising two electrode pairs, where the principle of adhesion and repelling effect is exploited to capture the contaminating particles, characterized in that the electrodes (7) each comprise a collector (5) and a separator (6) are connected to the positive or negative high voltage (8, 9) and a cover (14) is connected to a zero potential (10), thereby giving a positive charge to one electrode (7) and a negative charge to the other electrode (7) of the electrode pair, and then the contaminating particle molecules stuck to the positively charged separator (6) are pushed away by the repelling effect of the identical charges, so that the molecule moves to the collector (5) of the neighbouring negatively charged electrode (7), and it joins and coagulates the other molecules that are already stuck there and have an opposite charge, and the pair continues the process and keeps moving through the electrodes (7), and the coagulated pairs move through the filter module (1) and their mass is increased by the powers of two until they reach a size needed for them to fall out of the airflow, and they get stuck either to one of the electrodes (7) fitted with a collector (5), or to the cover (14) that has a zero potential (10), so that the flow of air is facilitated so that the contaminating particles could be removed from the airflow, thereby allowing for the cleaning of the air with high efficiency.

2. The method according to claim 1, characterized in that the separation of the contaminating particles from the airflow is carried out with taking into account one or more operating parameters, selected from the group consisting of the initial size, the speed of flow, and the number (n) of the filter modules (1).

3. The method according to claim 1, characterized in that the high flow velocity and the separation of contaminating particles with an initial size in the nano-range is achieved by using more filter modules (1) than in the case of lower flow velocity or when the size of the contaminating particles to be removed is in the micro-range.

4. The method according to claim 1, characterized in that, in order to reverse the direction of the airflow to be cleaned, the electrode pairs of the filter modules (1) are fitted into the individual filter modules (1) in mirror position, and they are also closed by a cover turning part (19) at the end that is opposite to the original flow direction.

5. The method according to claim 1, characterized in that the air to be cleaned, in addition to being cleaned, is moved like a quasi-electrodynamic linear engine, so that the mass and/or size of the coagulated particles is increased by the powers of two as necessary while passing through two sequential filter modules (1), up to 220 value.

6. A filter module for the cleaning of air containing small contaminating particles with high efficiency, characterized in that it is fitted with two or more electrodes (7), composed of a collector (5) and a separator (6) located at a given distance, which are connected to a positive or negative high voltage (8, 9) and are surrounded by a cover (14) consisting of a base plate (2), connected to a zero potential (10), one or more side plates (12), and a cover plate (11), wherein the two or more electrodes (7) are connected to the opposing positive or negative high voltage (8, 9) and to the zero potential (10) form an electrode pair, wherein two electrode pairs form a filter module (1), where the electrode pairs are placed so that there is one electrode (7) of the opposite potential installed between two electrodes (7) of the same potential.

7. The filter module according to claim 6, characterized in that, in order to reverse the direction of the airflow to be cleaned, the electrode pairs of the filter module (1) are installed in the individual filter modules (1) in mirror position, and they are closed with a cover turning part (19) at the end opposite to the original direction flow.

8. An air cleaning device composed of one or more filter modules (1) according to claim 6 characterized in that, in order to achieve high flow velocity and the sufficient increase in size and mass of the contaminating particles, two or more filter modules (1) are connected to each other in a serial and/or parallel position.

9. The device according to claim 8, characterized in that, in order to capture particles the size of which is 0.1 micrometre or larger, the filter modules (1) are connected in a parallel position along their vertical axis in a releasable manner.

10. The device according to claim 9, characterized in that, in order to capture nanometre or molecule sized particles, the filter modules (1) are connected to each other serially and in a releasable manner through their side plates (12) along their longitudinal axis that is perpendicular to the vertical axis.

11. The device according to claim 9, characterized in that, in order to increase the cleaning efficiency as desired, the filter modules (1) are connected in parallel and serial positions.

12. The device according to claim 8, characterized in that, in order to connect to large industrial devices, the filter modules (1) are fitted with a sensor module (15) containing one or more sensors (16) placed at the input and output openings, with a control unit (18), and with a power supply unit (17) enabling the operation of the device.

13. The device according to claim 12, characterized in that the sensor modules (15) and the sensors (16) are designed to be able to measure and display the contamination level and characteristics of the inbound and outbound air, as well as to ensure compliance with the required level of air quality, and to regulate the operating positive or negative high voltage (8, 9) as required.

14. The device according to claim 13, characterized in that the control unit (18) is designed to be able to receive and transmit the signals concerning the values measured by the sensors (16), and to regulate the level of the positive or negative high voltage (8, 9) that ensure the operation of the device.

15. The device according to claim 14, characterized in that the power supply unit (17) is designed to be able to run on 230 V network power, battery, or solar panel.

Description

[0018] The solution according to the invention is presented in more detail on the basis of the following drawings:

[0019] FIG. 1 shows the front view of an advantageous implementation of the filter module according to the invention,

[0020] FIG. 2 shows the axonometric drawing of two filter modules before they are connected in a parallel position,

[0021] FIG. 3 shows the front view of three filter modules connected in serial position, with a sensor module on both ends,

[0022] FIG. 4 shows the axonometric drawing of four filter modules when connected in a parallel position,

[0023] FIG. 5 shows the axonometric drawing of two filter modules when installed in mirror position,

[0024] FIG. 6 shows the axonometric drawing of three filter module pairs connected and installed in a parallel mirror position,

[0025] FIG. 7 shows the theoretical drawing of two serially connected filter modules when installed in an existing pipe.

[0026] For the purpose of this invention, mirror installation means that the filter module 1 is mounted on the opposite side (backside) of the base plate 2, rotated by 180 degrees, and is fitted with a cover turning part 19.

[0027] FIG. 1 shows the front view of an advantageous implementation for of the filter module 1 according to the invention. The filter module 1 is mounted onto the base plate 2, which is connected to zero potential 10, just like the side plates and the cover plate that are not show on the drawing. The drawing also shows the two electrode rails 3 with four insulation blocks 4 and connected to the positive high voltage 8 or the negative high voltage 9. Positive high voltage 8 and negative high voltage 9 is produced by the power supply unit 17 shown on FIG. 3. The four electrodes 7, each consisting of a collector 5 and a separator 6, are connected to the two electrode rails 3. The two opposing electrodes 7, connected to the positive high voltage 8 and negative high voltage 9 respectively, as well as to the zero potential 10, for an electrode pair, and two electrode pairs form the filter module 1, in which the electrode pairs are installed so that one electrode 7 of the opposite potential is installed between two electrodes 7 of the same potential, as shown on the drawing clearly.

[0028] FIG. 2 shows the axonometric drawing of two (n=2) filter modules 1 before they are connected in a parallel position. The drawing indicates the base plate 2, the vertical cover plate 11 (front plate), one side plate 12, and four connecting bores 13 on the base plate 2. The base plate 2, the cover plate 11, and the two side plates 12 form the cover 14 of the filter module 1.

[0029] FIG. 3 shows the front view of three (n=3) filter modules when connected in a serial position, with one sensor module 15 at each end of the structure, which can be connected to large industrial devices, for example, they can be built into existing air supply systems. One, advantageously more sensors 16 are mounted onto the 2 inlet and outlet openings of the filter modules 1 on the ends of the structure. Each filter module 1 is fitted with a power supply unit 17 that powers the control unit 18 and the sensor module 15 housing the sensors 16. The sensor modules 15 and the sensors 16 are designed to be able to measure and display the contamination level and characteristics of the inbound and outbound air, as well as to ensure compliance with the required level of air cleanness, and to regulate the positive or negative high voltage 8, 9 as required. The control unit 18 is designed to be able to receive and transmit the signals concerning the values measured by the sensors 16, and to regulate the level of the positive or negative high voltage 8, 9 that ensure the operation. The power supply unit 17 powering the individual units and the sensors 16 is designed to be able to run on 230 V network supply, battery, or solar panel.

[0030] The arrows on the drawing indicate the direction of the airflow. The arrow on the left side indicates the flow of inbound and contaminated air, while the arrow on the right side indicates the departure of the leaned air.

[0031] FIG. 4 shows the axonometric drawing of four filter modules connected in a parallel position, meaning that the number n of the filter modules 1 is equal to four.

[0032] In such a situation, the four filter modules 1 are mounted onto each other in a releasable manner in a parallel position and along the axis that is perpendicular to the position shown on FIG. 2. The figure shows the filter module 1, the base plate 2, the electrode rail 3, the insulation block 4, and the collector 5 and separator 6 parts of the electrode 7. The arrows shown on the drawing and pointing toward the same direction indicate the direction of the inbound contaminated air to be cleaned.

[0033] FIG. 5 shows the axonometric drawing of two (n=2) filter modules when installed in a mirror position. In such a situation, the two filter modules 1 are connected to each other in a releasable manner in a parallel position along their vertical axis. The drawing shows the filter module 1, the base plate 2, the electrode rail 3, the insulation block 4, the collector 5, the separator 6, and the cover turning part 19 used to reverse the flow direction of the air the be cleaned. In such a situation, the electrode pairs of the filter module 1 are installed in the individual filter modules 1 so that they mirror each other, and they are closed by the above-mentioned cover turning part 19 at the ends that are opposite to the original flow direction. The cover turning part 19 has a half-pipe or reversed U shape advantageously. The contaminated air to be cleaned is flowing in the upper left part of one filter module 1 toward the separator 6, while the cleaned air is leaving in the lower right part of the other filter module 1, as also indicated by the arrows on the drawing.

[0034] FIG. 6 shows the axonometric drawing of three filter module 1 pairs (n=6) connected in serial mirror position. The filter module pairs installed in mirror position are connected to each other serially in a releasable manner, so that the filter modules 1 of the pair in the middle are connected to the neighbouring filter modules 1 with a flexible pipe 20.

[0035] In addition to the filter modules 1 and the flexible pipes 20, the drawing also shows the cover turning parts 19 and the direction of the airflow.

[0036] FIG. 7 shows the theoretical drawing of two serially connected filter modules 1 built into an existing pipe 21. The two filter modules 1, fitted with a power supply unit 17 and a control unit 18, are built into a shape having a circular cross-section, such as an air exhauster. Relative to the lower filter module 1, the other filter module 1 on top is rotated in a 90 degree angle because doing so improves the air cleaning efficiency. The two arrows in the bottom of the drawing indicate the flowing direction of the air to be cleaned, while the upper arrow indicates the flow direction of the cleaned air.

[0037] With regard to the above considerations, the air cleaning device implemented with the procedure and filter modules 1 according to the invention operates as follows. The air to be cleaned is channeled to the device composed of the appropriate n number of filter modules 1 according to the invention, each consisting of two electrode pairs, and the device sucks in and moves the air. The principle of adhesion and repelling effect is exploited to capture the contaminating particles. During the operation, the electrodes 7, each consisting of a collector 5 and a separator 6, of the electrode pair is connected to the positive or negative high voltage 8, 9 generated by the power supply unit 17 and their cover 14 is connected to the zero potential 10.

[0038] This way, one electrode 7 of the electrode pair has a positive charge, the other electrode 7 has a negative charge. The contaminating particle molecule that gets stuck to the positively charged separator 6 is pushed away by the repelling effect of the identical charges, so that the molecule moves to the collector 5 of the neighbouring negatively charged electrode 7, and it joins and coagulates the other molecules that are already stuck there and have an opposite charge, and the pair continues the process and keeps moving through the electrodes 7. Then, the coagulated pairs move through the filter module 1 and their mass is increased by the powers of two until they reach a size needed for them to fall out of the airflow, and they get stuck either to one of the electrodes 7 fitted with a collector 5, or to the cover 14 that has a zero potential 10. All in all, the flow of air is facilitated by two effects, i.e. the pulling effect of the airflow and the repelling effect of particles having the same charge, until the adhesive power of the particles, having a continuously increasing mass, becomes stronger than the repelling effect of identical charges and until the contaminant falls out of the airflow due to its increased mass, so that the contaminating particles could be removed from the airflow, thereby allowing for the cleaning of the air with high efficiency.

[0039] In the course of the procedure, the separation of the contaminating particles is carried out with regard to the operating parameters, such as the initial size, the speed of flow, and the n number of the filter modules 1.

[0040] In the course of the procedure, high flow speed and the separation of contaminating particles with an initial size in the nano-range is achieved by using more filter modules 1 than in the case of lower flow speed or when the size of the contaminating particles to be removed is in the micro-range.

[0041] According to the task, it might be necessary to reverse the direction of the airflow to be cleaned. In such a situation, the electrode pairs of the filter modules 1 are fitted into the individual filter modules 1 in mirror position, and they are also closed by a cover turning part 19 at the end that is opposite to the original flow direction, as shown on FIGS. 5 and 6.

[0042] In the course of implementing the procedure according to the invention, the air to be cleaned, in addition to being cleaned, is moved like a quasi-electrodynamic linear engine, so that the mass and/or size of the coagulated particles is increased by the powers of two as necessary while passing through two sequential filter modules 1, up to 2.sup.20 value, which is over one million times of the original size.

[0043] The most important unit of the air cleaning device according to the invention is the filter modules designed according to this invention.

[0044] The filter module 1 has electrodes 7, which are composed of a collector 5 and a separator 6 located at a given distance from the collector 5, are connected to a positive high voltage 8 or negative high voltage 9, and are surrounded by a cover 14 consisting of a base plate 2, connected to zero potential 10, side plates 12, and a cover plate 11. Two electrodes 7 connected to the opposing positive or negative high voltage 8, 9 and to the zero potential 10 form an electrode pair, and two electrode pairs form a filter module 1. The electrode pairs are placed in the filter module 1 so that there is one electrode 7 of the opposite potential installed between two electrodes 7 of the same potential.

[0045] Two filter modules 1 may be used to implement a twin module that may be also used advantageously. As noted above, certain tasks may require the flow direction of the air to be cleaned to be reversed. In such a scenario, the electrode pairs of the filter module 1 are installed in the individual filter modules 1 in mirror position, and they are closed with a cover turning part 19 at the end opposite to the original direction flow.

[0046] Using the filter modules 1 described above, an air cleaning device according to the invention may be implemented that is fitted with n number of filter modules 1, connected to each other in serial and/or parallel positions depending on the task, in order to achieve the desired increase in size and mass of the contaminating particles. The cleaning efficiency may be increased as necessary by using mixed connection.

[0047] The number n of the filter modules 1 is determined by taking into account that the mass and/or size of the coagulated particles increases while passing through two subsequent filter modules 1 by the powers of two, up to the value of 2.sup.20, when the original size reaches the threshold that allows the contaminating particles to be filtered or separated with certainty.

[0048] In order to capture particles the size of which is 0.1 micrometre or larger, the filter modules 1 are connected in a parallel position along their vertical axis in a releasable manner.

[0049] In order to capture nanometre or molecule sized particles, the filter modules 1 are connected to each other serially and in a releasable manner through their side plates 12 along their longitudinal axis that is perpendicular to the vertical axis.

[0050] In both cases, the releasable joining works without damaging; it may be, for example, a screw connection for parallel connection, or, for example, a screw connection or cam-type closure for serial connection.

[0051] When connected to large industrial devices, the filter modules 1 are fitted with a sensor module 15 containing sensors 16 placed at the input and output openings, with a control unit 18, and with a power supply unit 17 enabling the operation of the above, as shown on FIG. 3.

[0052] The sensor modules 15 and the sensors 16 are designed to be able to measure and display the contamination level and characteristics of the inbound and outbound air (e.g. flow velocity, humidity, temperature), as well as to ensure compliance with the required level of air cleanness, and to regulate the operating positive or negative high voltage 8, 9 as required.

[0053] The control unit 18 is designed to be able to receive and transmit the signals concerning the values measured by the sensors 16, and to regulate the level of the positive or negative high voltage 8, 9 that ensure the operation.

[0054] In an advantageous implementation example, the control unit 18 may also be implemented within the power supply unit 17 as a subunit thereof.

[0055] The power supply unit 17 is designed to run on 230 V network power, a battery, or a solar panel, because only a small electric performance is required, which is 10.sup.3/h, approximately 1 W to move and clean the air.

[0056] When implementing the air cleaning device according to the invention, the insulation block 4 is made of ceramics, glass, or plastic, the base plate 2 is a metal sheet, the cover 14 is made of metal or plastic, the cross-section of the collector 5 of the electrode 7 is significantly larger than the cross-section of the separator 6, the relationship between the two cross-sections being at least four.

[0057] The operating positive or negative high voltage 8, 9 of the electrodes is a few kV, at least 4 kV.

[0058] As needed, filter modules 1 with 20 m.sup.3/h, 150 m.sup.3/h, or 500 m.sup.3/h capacity may be produced, and they may also be connected to each other in serial and/or parallel position according to the required level of efficiency.

[0059] For industrial application, filter units with, for example, 20,000 m.sup.3/h capacity may also be constructed by combining filter modules 1 of 500 m.sup.3/h capacity.

[0060] The solution according to the invention may be used in versatile ways, especially on the following fields: [0061] on the field of civil environmental protection, as stand-alone, pre-, or post-filter, such as: [0062] cleaning the air and exhaust gas in the chimney of industrial plants (foundry shops, paint shops, plants causing chemical pollution); [0063] cleaning polluted urban air (traffic junctures, tunnels, hazardous smog locations etc.); [0064] cleaning, de-germination, and filtering pollen from the air closed premises (hospitals, laboratories, restaurants, residential rooms etc.); [0065] military application on the field of NBC safety as a pre-filter.

[0066] The solution according to the invention achieved its purposes and has the following advantages: [0067] it may be used to capture contaminating particles that are smaller than one micrometre and are in the nanometre range, and to separate molecule-sized solid, chemical, and biological contaminants; [0068] it has a modular structure; [0069] the air may be moved without a ventilator and running in a silent mode; [0070] no filter cartridge is needed; [0071] the direction of the flow may be reversed easily; [0072] cleaning is highly efficient, approximately 95%; [0073] energy efficiency; [0074] economic operation; [0075] simple and cheap maintenance; [0076] easy to install in existing systems.