SE534339C2 - Methods and apparatus for purifying air by trapping air in the liquid - Google Patents

Abstract

Device for purifying air by trapping airborne contaminants in a liquid comprising a filter with an air inlet part with a coarse filter (37), at least one filter part (38, 39, 40) with a liquid receiving space (51), atomization of inflowing air in the form of nets, grids or perforated disc (46) with fine holes (47) in the liquid-receiving space (51) and a rim (48) surrounding said atomizing means for trapping air which via a cent a space hole (43) and a gap (50) between a hood (45) immersed in the liquid space and a wall (44) surrounding the center hole flow into a liquid in said liquid receiving space, and an outlet part (4) comprising a foam-breaking wire filter (11), a fan wheel (12) as well as a motor (10) which drives said fan wheel (12), wherein an optional number of filter parts (38, 39, 40) can be arranged between the air inlet part and the air outlet part (4). (Fig. 8)

Description

20 25 30 534 339 The amount of water vapor in air varies with the temperature of the air and the relative humidity. If free water and steam formation heat are available, the air absorbs more moisture to full moisture saturation, ie. 100% relative humidity, for prevailing air temperature. Due to this, air that passes through air purification systems based on water baths or water spray will absorb water and add more and more moisture to the room. High moisture content can cause inconveniences such as. mold.

The amount of water released from this type of air purification system can be reduced in various ways. If supplied air and possibly also the water is cooled before air and water are mixed, the amount of available evaporating heat is reduced, whereby evaporation is reduced or prevented. Alternatively, purified air that has received an undesirably high moisture content can be caused to pass through an air dehumidification system before the purified air is released into the room. However, both alternatives increase both cost and energy consumption for air purification.

In slaughterhouses, the food industry, laboratories and hospitals, it is important to reduce the amount of airborne, inorganic particles as well as organic pollutants and infectious agents. In airplanes, trains, office premises and in homes, air purification is also necessary or desirable here.

Every degree of air purification can be very important. For an increased degree of air purification, such as for pollen, spores, bacteria and viruses, the system's complexity, cost and maintenance needs increase.

There is thus a need for simple and preferably substantially maintenance-free air purification systems which are nevertheless relatively effective within a wide range of sizes for airborne particles. In this case, liquid-based systems are preferable to mechanical filters, which at the small mesh sizes required to remove small particles are quickly clogged and must be replaced. At the same time, the air's ability to absorb water creates an obstacle to the creation of simple and inexpensive air purifiers based on water filters.

The invention An object of the present invention is to provide a device for removing airborne particles in an efficient manner without undesired effect on the composition and / or moisture content of the air and without requirements for post-treatment of the air.

This is achieved with the device according to the invention as defined in the independent claim.

Further developments and preferred embodiments of the invention are set out in the subclaims.

Brief description of the drawing The invention will be described in more detail below in connection with exemplary embodiments of a device according to the invention shown in the schematic drawings, wherein Fig. 1 shows a view of an air purification device for illustration of the principle of the invention, Fig. 2 shows a view corresponding to Fig. 1 with the device in idle position, Fig. 3 shows a view corresponding to those in Figs. 1 and 2 with the device in operating position, Fig. 4 shows a variant of the air purification device according to Fig. 1, Fig. 5 shows a further variant of Fig. 6 shows a further variant of the air purification device, Fig. 7 shows a further development of the air purification device according to Fig. 6, and Figs. 8 and 9 show the air purification device according to the invention with three filter stages, in rest position and in operating mode.

Detailed Description of the Invention The present invention thus relates to a device for purifying air without the attendant disadvantage that the air is undesirably saturated with respect to the liquid used.

The invention will now be described in more detail with reference to the accompanying schematic drawings.

In order to explain the principle underlying the air purification device according to the invention, Figs. 1-3 show schematic views of a device for air purification, which is covered by the Swedish patent application 0900131-4, in the form of a filter 1 consisting of a lower, preferably cylindrical with a container 3 provided with a bottom 2 and with an upper, preferably conically tapered outlet part 4 with an outlet opening 5. In the container 3 a stirrer in the form of a disc provided with holes 6 is arranged 7. The disc has a downwardly directed tight-fitting disc frame 8. The disc sits on a shaft 9 which is rotated by means of a motor 10. In a transition area between the container 3 and the outlet part 4, in the embodiment shown, a filter 11, t .ex. in the form of a wire filter. Furthermore, in the embodiment shown on the shaft 9, a fan wheel 12 is arranged between the outlet opening 5 and the filter 11.

Air to be purified in the filter 1 is led in at the bottom 2 of the filter to pass therethrough. In the embodiment shown, the air is then passed through a coarse filter 13, which runs around the filter outside in the transition area between the container and the outlet part and down into an air gap 14 which is delimited between the wall of the container 3 and an interior lying inside it. cylindrical partition 15, which extends from said transition area down to a piece above the bottom of the container, and then further parallel to the bottom while leaving an air inflow opening 16 centrally in the filter.

Fig. 2 shows the filter 1 according to Fig. 1 in the rest position, whereby a liquid 18 partially fills the container 3. Furthermore, it appears that the filter 1 also has a by-pass line 19 through which liquid can be drained off and by means of a pump 20. driven by a liquid filter 21 to remove particulate matter trapped in the liquid. By means of a pressure measuring device 22, which measures the pressure before and after the filter, and which can be combined with an alarm, an indication is obtained that the filter needs to be cleaned.

Fig. 3 shows the air filter device according to Fig. 1 in operating mode, whereby the air flow is indicated by arrows. The air to be purified is led by means of negative pressure and / or overpressure into the filter and then flows in under the stirrer. The negative pressure created by the fan wheel 12 above the liquid level causes the air to travel upwards through the liquid bath. When the air is forced to pass the agitator, which simultaneously rotates at high speed, air and liquid form a foam 23. In this foam, airborne particles adhere to the outer and inner foam walls of the liquid. On the upper surface of the foam layer, foam bubbles of the negative pressure expand and burst and an air that is cleaner than the incoming air is released. The air then passes through the mechanical wire filter 11, where liquid splashes from the agitation and lack of liquid bubbles get stuck. By arranging an air cone 24 in front of the wire filter, an increased flow rate is created, whereby the negative pressure is strengthened and thereby the foam is ruptured even more efficiently. The purified air then passes out of the filter through the outlet opening 5.

The wire filter II may also be electrically charged to thereby break the surface tension of liquid bubbles which have not burst despite the prevailing negative pressure.

Liquid released from lack of foam accumulates on the top of the foam layer and will flow back to the bottom of the container due to gravity. The air cone 24 forces the foam towards the center of the container, whereby the upper side of the foam layer obtains a slope from the center and out towards the edges of the container. The slope leads accumulated liquid towards the edges of the container, where return liquid 25 can flow downwards, past the foam, through the gap between the disc frame 8 and the walls of the container to the underside of the disc 7.

Preferably, the filter is operated periodically, whereby when the filter is at rest and the liquid is still in the container, liquid from the bottom part of the liquid column is drained and pumped through the liquid filter. During the operation of the filter, when the foam breaks, the liquid in the foam walls will run down along the walls of the filter towards the bottom of the container. The concentration of contaminants in the liquid is judged to be highest at the bottom of the container, whereby an effective purification is achieved with the aid of the liquid filter in the by-pass line.

By using a liquid which has a low vapor pressure at the current air temperature, such as an oil, glycerin or other non-toxic liquid, the great advantage over the prior art is achieved that the moisture content of the air does not change during the purification. In this context, low vapor pressure means that the liquid does not evaporate at the prevailing pressure and temperature and thus practically does not occur in the purified air. 10 15 20 25 30 534 339 I e.g. countries and premises where the humidity is already so high or low that any increased humidity does not become a disadvantage or perhaps even an advantage, it may be possible to use water as a liquid in the method and device according to the invention. In this case, in order to promote foaming, it may be expedient to add surfactants or other foaming-promoting additives.

To achieve a desired humidification of air, water can be added to a liquid with low vapor pressure in the filter. This can be done on the basis of the measured moisture content in incoming air, whereby at the same time as the purification of the air a controlled air humidification can be achieved for e.g. a local.

It should be noted that already by allowing air to bubble through a liquid, a certain purifying effect is achieved, which is known per se. By arranging a stationary fine-mesh grid or a perforated disc, a fine distribution of the air is achieved, whereby the foaming is favored and thus a dramatically improved cleaning effect is achieved. By combining this with a stirrer function as in the device according to the embodiment discussed above, further improved effect is achieved. In the following, further embodiments and variants thereof will be described, only the parts which differ from previously described embodiments will be discussed.

Fig. 4 shows a variant of the air purification device according to Fig. 1, which lacks a stirrer. Instead, in connection with the cylindrical partition wall 15, a middle bottom is arranged in the form of a disc 26. provided with fine holes. . Fig. 5 shows a further variant, which differs from the previous one in that it has a downwardly facing fine-mesh grille hood 27 arranged over an air inlet 28 in a bottom 29 which is connected to the cylindrical partition wall 15.

Fig. 6 shows a further variant of the filter, which differs from the first embodiment shown in Figs. The motor 10 then drives both the fan wheel 12 and the grille hood 30.

Fig. 7 shows a further development of the device shown in Fig. 6 with two fine-mesh grid hoods 31, 32 arranged one above the other. In connection with the motor 10 which drives the fan wheel 12, a gear 33 is arranged via which the motor 10 drives a first shaft 34 on which the grid hood 31 located closest to the bottom of the filter is arranged as well as a hollow shaft 35 which concentrically encloses the first-mentioned shaft on which the second the grille hood is arranged, the gear unit being designed such that the grille hoods 31, 32 are driven in opposite directions of rotation.

The mixture of air and liquid becomes extremely efficient with two grid hoods rotating in opposite directions at a mutual distance so adapted that the foam from the first grid hood 31 is trapped by the second grid hood 32. The probability that even extremely small particles still float freely on the outside or the inside of foam bubbles after the first grid hood will stick to liquid when the upper grid hood partially tears bubbles and when new bubbles are formed, is very large.

Fig. 8 and Fig. 9 show the filter according to the present invention in the form of a three-stage filter 36 at rest, with drawn air flow and in operation with foaming, respectively. The working principle of the filter according to the invention is the same as for the air purification devices described above. 5. The air flows in through a coarse filter 37 at the bottom of the filter. Each filter stage 38, 39, 40 consists of a cylindrical container 41 with a bottom 42 and a central opening 43 surrounded by an upwardly directed cylindrical wall 44 to form a liquid receiving space 51. At a distance above the cylindrical wall 44 a upward to a tapered cap 45 whose sides extend down into the container outside the cylindrical wall 44 surrounding the center hole. Adjacent to the lower edge of the hood is arranged a atomizing device 46 in the form of a grid or a disc with fine openings 47 which let the air through as fine bubbles. The disc or grid is surrounded by a downwardly directed rim 48 which traps the air and forces it through the small openings 47. This leads to the formation of foam 49, as shown in Fig. 9. When the foam ruptures and the air rises further below In the next step, the air is forced down into the gap 50 between the hood and the cylindrical wall 44 surrounding the center hole 43.

The liquid can advantageously be added in the top last step, to e.g. by siphoning, it is gradually drained to the nearest underlying stage so that the purest liquid is present in the last stage and the most soiled liquid is present in the first stage where the coarsest particles in the polluted air are captured. the liquid in the first step can then be purified periodically as described above, to then be returned in the process to the last step. The liquid filter and the liquid pump can then be placed in the bottom of the device. 534 339 The filter according to the invention as described above in connection with Figures 8 and 9 is of course not limited to three steps, but it can be designed with from 1 step to any desired number of steps. It should be borne in mind that the motor and fan wheels must be adapted so that the required air speed to achieve foaming is achieved to the required degree.

Filters that work without agitators have the advantage that they are simpler and cheaper to design, and the tolerance requirements are not as high when rotary agitators are not to be installed.

One or more of the filter stages 38, 39, 40 may be equipped with agitators. Thus, in an air purification plant, the different filter variants can be combined into an air purification plant in several stages analogous to that shown in Figs. 8 and 9. For example, in a first stage, a filter without a stirrer, such as a filter part 38, can be used. in a second step a filter with a stirrer and in a third step a filter with double counter-rotating stirrers, or any other desired combination, motivated by prevailing circumstances, such as the type of pollutants, set requirements for the purified air, etc.

Claims (7)

10 15 20 25 30 534 339 ll Patent claim Device for purifying air by capturing pollutants present in the air in a liquid comprising a filter (1) with an inlet (16) and an outlet (5) for polluted and purified air, respectively, a liquid arranged in the filter (1) 18), means (10, 12) for driving the air through the filter (1), atomizing means (7) arranged in the filter for mixing air and liquid and forming foam (23) as well as means (11) for breaking the foam so that the liquid with contaminants trapped therein remains in the filter, characterized in that it has an air inlet part with a coarse filter (37), at least one filter part (38, 39, 40) consisting of an upwardly open container with a central bottom hole (43) and a hole surrounding wall (44) for forming a liquid receiving space (51) between the outer wall (41) of the container and the wall (44) surrounding the bottom hole, a hood element (45) arranged over said central bottom hole and which hood is arranged to extend down in said liquid-receiving space ( 51), and having at its lower edge atomizing means in the form of nets, grids or perforated disc (46) with fine holes (47) and a rim (48) surrounding said atomizing means for trapping air which via the center hole (43) and a gap (50) between hood (45) and the wall (44) surrounding the hole flows down into a liquid in said liquid receiving space, and an outlet part (4) comprising a foam breaking wire filter (11), a fan wheel (12) as well as a motor (10 ) which drives said fan wheel (12), wherein an optional number of filter parts (38, 39, 40) can be arranged between air inlet part and air outlet part (4). 10 15 20 25 534 339 12 Device according to claim 1, characterized in that in addition to at least one filter part (38, 39, 40) it comprises at least one further filter part having at least one stirrer (7; 27; 30; 31, 32). Device according to Claim 1, characterized in that the atomizing means consist of at least one stirrer (7) in the form of a motor-driven plate (6) provided with holes (6) or a fine-mesh net or grid (27; 30; 31, 32; 46) , and that the inlet (16) for air is arranged under said disc, grid or net. Device according to one of Claims 1 to 3, characterized in that it comprises a purification device for purifying the liquid from the pollutants collected from the air in the form of a by-pass line (19) provided with a pump (20) and a liquid filter arranged in the line. (21). Device according to Claim 4, characterized by a pressure measuring device (22) in connection with the liquid filter for determining whether there is a need for regeneration or replacement of the filter. Device according to one of the preceding claims, characterized in that the liquid is a liquid which does not evaporate at the prevailing pressure and temperature, such as an oil, glycerol or other non-toxic liquid with a correspondingly low vapor pressure. Device according to claim 6, characterized in that water is dosed to the liquid based on measurement of the moisture content of the incoming air for a simultaneous controlled humidification of the purified air.