Air Purification Device

Abstract

An integrated autonomous air purification device for taking in polluted air, carrying it through the inside of the purification device where it passes through a set of filtering elements (1) that trap the dust particles contained in the air; ultraviolet-light lamps (2) that transform NO.sub.X and CO gases in the air into harmless compounds; an activated carbon filter (4) that traps and eliminates the volatile organic compounds and inorganic acidic gases; second filtering elements (5) that carry out a second filtering; and an extraction hood (6) configured to direct the air coming out of the second filtering elements (5) to at least one nozzle (7) that expels the air to the outside of the purification device.

Claims

1. An autonomous integrated air purification device comprising intake means, configured for taking in air from a nearby environment with particles and polluting gases, and carrying it through the inside of the air purification device, the purifcation device further comprising: first filtering configured to trap the dust particles contained in the outside air and to enable passage of said air, taken in by the intake means to the purification device; ultraviolet-light lamps inside rectangular ducts, wherein said ducts are impregnated with a photocatalytic compound configured for, in combination with ultraviolet light generated by the ultraviolet light lamps, transforming the NO.sub.x and CO gases contained in the air coming out of the first filtering elements into harmless compounds; an activated carbon filter configured to trap and eliminate volatile organic compounds and inorganic acidic gases contained in the air that has passed through the rectangular ducts; second filtering elements configured to enable the passage of the air coming out of the activated carbon filter; and to trap the passage of particles contained in said air coming out of the activated carbon filter; and an extraction hood configured to direct the air coming out of the second filtering elements to at least one nozzle n configured to expel said air to the outside of the purification device, by means of propulsion generated by at least one motor, wherein the outside air enters through a lower end of the purification device and goes up, passing through the elements that make up the device, to come out of the device through an upper end through the nozzle with a lower concentration of particles and polluting gases than a concentration of the inlet air.

2. The air purification device according to claim 1 further comprising a rectangular prism structure in a vertical position which comprises means for lifting off the ground and a perforated lower surface through which the air inlet is done, generated by the intake means.

3. The air purification device according to claim 1, wherein the first filtering elements comprise at least two means for trapping particles, the at least two means for trapping particles comprising: a first retention means, for coarse dust, configured to carry out pre-filtration of the device, trapping particles greater than 10 μm in diameter, the first retention means comprising at least: a first G2 type filter; and a second G4 type filter with a high capacity broken surface; and a second trapping means, for fine dust, comprised of a third M6 filter comprising glass microfibres, configured to accumulate the trapped dust.

4. The air purification device according to claim 1, wherein the rectangular ducts are configured to increase the speed of the air flow coming out of the first filtering elements and to convert said air flow into a turbulent one, increasing the contact of said air with the rectangular ducts, where the photocatalytic compound is located.

5. The air purification device according to claim 1, wherein the activated carbon filter comprises granules that are impregnated with alumina.

6. The air purification device according to claim 1, the second filtering elements further comprising: a fourth G4 type filter, configured to trap any particle that has come off from the first filtering elements and from the activated carbon filter; and a fifth F9 type filter configured to trap 99% of the PM.sub.10, PM.sub.5 and PM.sub.2.5 particles.

7. The air purification device according to claim 1, wherein the nozzle is configured to expel the air to the outside of said device and configured to vary the air outlet direction, as the nozzle is connected to the purification device by means of a ball-and-socket joint.

8. The air purification device according to claim 1 further comprising a first set of sensors configured to measure in real time, at least one of environmental parameters selected from: temperature, pressure, humidity, gas concentrations of NOx, SOx, COx, O.sub.3, and PM.sub.10, in ppb and in mg/m.sup.3, of the air taken in by the intake means of the integrated autonomous device.

9. The air purification device according to claim 1 further comprising a second set of sensors configured to measure the wear of at least one of the filters.

10. The air purification device according to claim 1, further comprising a computer system and at least one interactive monitor configured to display information on at least one of parameters that define the operation of the device and at least one of parameters measured by sensors of the device.

11. The air purification device according to claim 1 further comprising at least one universal connector (USB) configured to: connect the purification device by means of cable to an electronic device; charge battery of electronic devices; and carry out a data transfer from the device to a storage device.

12. The air purification device according to claim 1 further comprising connection means selected from a group comprising of 3G connectivity, 4G connectivity, LAN connection or WIFI connectivity.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0052] FIG. 1 shows an exploded perspective of the air purification device, enabling observing all the components comprised by said purification device.

[0053] FIG. 2 shows a detail of the rectangular obstructions with the ultraviolet-light lamps inside.

[0054] FIG. 3 shows an elevated perspective of the complete assembled device.

DESCRIPTION OFA PREFERRED EMBODIMENT

[0055] As can be seen in FIG. 1, the invention consists of an autonomous air purification device wherein the air is captured through the lower portion and passes through different filtering elements that capture and/or destroy the pollutants. Finally, the cleaned or purified air is released through the nozzles (7) located in the upper portion, to the outside.

[0056] The assembled device has a rectangular prismatic shape and is located in a vertical position, so that the inlet of the outside air, which can be polluted with both solid and liquid and gaseous particles, is carried out through the lower portion of said device, through a first coarse particle trapping barrier that facilitates the air intake but prevents the inlet of large lightweight elements such as sheets or plastics into the device.

[0057] To trap the inlet of solid particles dissolved in the air into the device, there are first filtering elements (1) located above the first coarse particle trapping barrier, which has two trapping means: [0058] a first coarse particle trapping means that has two filters in the direction of air flow: [0059] a first G2 type filter (11) to prevent the passage of coarse elements [0060] a second G4 type filter (12) with high capacity broken surface, for smaller elements such as soot. [0061] Above these filters, there is a second trapping means consisting of a third M6 type filter (13) with special glass microfibres that guarantee a low initial charge drop and an excellent capacity for accumulating particles.

[0062] By having three filters (11, 12 and 13) consecutively arranged, with different degrees of efficiency and arrestance, trapping is achieved in stages depending on the size of the particles, so that the filters (11, 12 and 13) are prevented from clogging quickly and requiring maintenance at short intervals.

[0063] The air coming out of the first filtering elements (1) flows through a plate that carries it through rectangular ducts (3) comprising ultraviolet-light lamps (2) inside them. The walls of these ducts (3) are impregnated with a layer of a photocatalytic compound that in combination with ultraviolet light causes the destruction of NO.sub.X and CO.

[0064] The air flow enters these ducts (3) or cavities at a higher speed due to the design of the ducts (3) and the constriction of passage with a constant flow, causing the flow to become a turbulent one, which maximises the contact between the air mass and the walls wherein the photocatalytic material is located, as shown in FIG. 2.

[0065] As can be seen in exploded FIG. 1, there is an activated carbon filter (4) in the upper portion of the rectangular ducts (3), half of said activated carbon being impregnated with alumina and the other half in a virgin state.

[0066] By means of this filter (4) the adsorption, absorption and/or oxidation for trapping and/or destroying VOCs and inorganic acidic gases such as NO.sub.X or CO.sub.2 of the air that has flowed through the rectangular ducts is achieved. Likewise, the elements that have not finished reacting in the photocatalysis step are removed and trapped in this filter.

[0067] The second filtering elements (5) are located in a position above the activated carbon filter (4). A fourth G4 type filter (51) and a fifth F9 type filter (52) that trap the possible elements that may have come off from the previous filters and ensure an elimination close to 99% of the PM.sub.10, PM.sub.5 and PM.sub.2.5 particles.

[0068] Once the air has passed through the second filtering elements (5) and is clean, it is carried by means of a hood (6) to a motor (8) that projects it at high speed through a series of nozzles (7) that are located on the sides of the upper portion of the device, so that the air is expelled at a distance of between 10 and 50 metres, to prevent the clean air from being taken in again, and to try to interlace the air flows with other devices, according to the arranged configuration.

[0069] The working ranges of the purification device are 24 hours a day, although they may depend on the weather conditions and atmospheric pollution, since, in case of taking in clean air, it is not necessary to carry out the purification processes.

[0070] To check the correct operation of the air purification device, a series of sensors are arranged to measure in real time environmental parameters such as temperature, pressure, humidity, concentrations of inlet pollutant gases or of dispersed solid particles, of the outside air taken in and of the air expelled through the extraction hood, as well as sensors to measure filter wear, relating the concentration of the amount of trapped particles with respect to the surface of the filtering elements in mg/m.sup.2.

[0071] To make the information read by these sensors known to the user, the device comprises a computer system connected to said sensors and to 4 interactive monitors located on the sides of the device, further configured to operate as a means of communication through the interactive screen, displaying information of interest to the users, such as air quality, public announcements, citizen information or advertising.

[0072] To facilitate the operation of the computer system, the device comprises USB type universal connectors, to connect to other electronic devices, to charge the battery or to exchange data from the device to the electronic device.

[0073] The device also comprises means of wireless connection such as 3G, 4G, or WIFI connectivity, or by means of cable via LAN connection, for the input and output of data from the device, and to be able to be controlled remotely.