ITVI990088A1 - PROCEDURE AND DEVICE FOR THE SANITATION OF AIR AND SIMILAR MIXTURES. - Google Patents

Description

TEXT OF THE DESCRIPTION

The present invention relates to a process and a device for sanitizing air and similar gaseous mixtures particularly, but not exclusively, useful in aeraulic and air-conditioning systems of hospitals, management centers and offices in general.

It is known that most modern buildings are equipped with sophisticated systems which ensure that the buildings themselves have suitable conditions of environmental well-being. In this context, the characteristics closely related to the chemical composition of the air such as low bacterial activity, absence of pollution, etc. have assumed, in the last decade, a very significant importance as it has been experimentally found that conventional plants are often the cause of the onset of some diseases. In fact, if scrupulous maintenance is not carried out at regular intervals on the system, consisting of effective cleaning and disinfection of the surfaces in direct contact with the air, the same and especially its ducts, as well as filters, etc. become the ideal location for the proliferation of viruses, molds and bacterial colonies such as the dreaded Legionella Pneumofila and Bacillus Cereus. On the other hand, the maintenance of the installed systems is an extremely heavy burden as it mainly depends on the development of the network of ducts that in multi-storey buildings such as hospitals, shopping centers, etc. it can be very extensive. The adoption of electrostatic precipitation filters partially solves the problem of the elimination of bacterial colonies thanks to the capture of the dust, as it is known that a multiplicity of bacteria are carried in the air free from the dust itself, preferably on particles with a few microns in diameter. . Experimental research has shown that ionized air has a very pronounced bactericidal effect. For example, the researchers Philips, Harris and Jones, by nebulizing a large amount of bacteria in an environment and subjecting them to ionization, have verified that, with positively ionized air, the mortality rate of the bacterial load is 54%, while, with negatively ionized air is 78%. A further confirmation of this phenomenon is due to the experiences of the researcher Lautie who ionized the air in a closed environment of 120m3 with an approximate concentration of 83,000 bacteria per cubic meter of air, noting that the latter rapidly diminished until it vanished. in about three quarters of an hour. Further confirmations are due to the researchers Kellog and Fratini who carried out experiments and measurements on Staphylococcus aureus and molds respectively. These experimental observations are explained by the fact that the ionization of air leads to the breaking of the bonds of oxygen molecules such as 02 and therefore to the formation of free oxygen 0 "which in the gaseous state, as an oxidant, exerts bactericidal and microbicidal action.

The main task of the present invention is to overcome the aforementioned drawbacks by creating a process and a plant for sanitizing the air and similar gaseous mixtures that give the treated air high purity characteristics both in terms of particulate matter and microbial.

Within the scope of this aim, an object of the invention is to provide a process and a system which allows to prevent on new systems and to eliminate the formation of molds and bacterial colonies along the channels for an almost unlimited time in existing ones. .

A further object of the invention is to provide a method and a plant which allows a substantial reduction over time in the maintenance interventions and specifically in the cleaning interventions along the ducts, thus extending the life of the plant itself.

Not least object of the invention is to provide a plant preferably consisting of modular modular units so as to contain the costs of production, those of installation and maintenance, as well as those of replacing the components.

This task, as well as these and other purposes which will appear better later, are achieved by a process for sanitizing the air and similar gaseous mixtures comprising the initial phase of aspiration of said air to be sanitized and the terminal phase of inlet of said sanitized air. in a closed environment, characterized by the fact of understanding the intermediate stages of:

- dedusting by electrostatic precipitation of said air to be sanitized;

- ionization that exerts a bactericidal and microbicidal action in said de-dusted air.

Advantageously, said ionization is negative and the concentration of negative ions per unit of dedusted air is higher by at least two orders of magnitude with respect to the concentration of ions naturally present and the concentration being constant over time.

This task, as well as these and other purposes which will become clearer hereinafter, are achieved by a device for carrying out the procedure for the sanitization of air and similar gaseous mixtures, comprising suction means and means for conveying said air to be sanitized and distribution means in a closed environment of said sanitized air, characterized in that it comprises, in the direction of the flow of said air to be sanitized in said conveyor means, dedusting means with electrostatic precipitation and ionizing means for said dedusting air.

Further features and advantages of the invention will emerge more clearly from the description of a preferred but not exclusive embodiment, illustrated by way of example, but not limiting, in the accompanying drawing tables, in which:

Figure 1 represents a schematic perspective view of the device according to the invention;

Figure 2 represents a detailed view of the device according to the invention;

Figure 3 represents a view of a closed environment incorporating the device according to the invention;

The procedure for sanitizing the air and similar gaseous mixtures includes an initial phase of continuous aspiration of the air to be sanitized. The latter will consist of extract air from the environment in which the sanitized air is emitted and external air, preferably in the proportion 70/30, in order to guarantee correct re-oxygenation of the environment itself and, at the same time, to contain the energy consumption by limiting air changes as much as possible. In particular cases, it will be possible to carry out the procedure only with return or external air. The air sucked in is subjected to a phase of energetic dedusting in two stages, respectively through a prefiltration and by electrostatic precipitation in order to capture most of the dust and with them any microbes, fumes, etc. dedusted air is treated to give it thermohygrometric characteristics suitable for the desired conditions in the environment in which it will be emitted. Therefore, the air itself is subjected to ionization which carries out a sterilization action of the bacteria and microbes that have survived the dedusting phase unscathed. Conveniently, the ionizing field is negative in order to strengthen the bactericidal and microbicidal action and, for the same reason, the concentration of negative ions released into the dedusted air is very high and constant over time. In principle, this concentration is equal to at least two orders of magnitude higher than the concentration normally present in free air, ie approximately 300,000 ions per cubic centimeter. After this passage, the excess ions, which therefore did not contribute to the sterilization process, are neutralized in order to restore the electrostatic balance in the dedusted air. At this point, the air is sanitized and is released into the environment. During this last phase, the same is again enriched with negative ions in order to restore normal electrical conditions.

With reference to the attached figures, the device, generally indicated by the reference number 4, is substantially constituted, in the direction of the air flow, by suction means 5 for the air to be sanitized, by dedusting means 6, by ionizing means 7 and by conveyor means 8 for connecting the sanitized air to distributing means 9 in a closed environment 10. In detail and with particular reference to Figures 2 and 3, the suction means 5, of a per se known type, continuously take in the fresh air through the duct 11 and, at the same time, suction through the grille 12 and to the subsequent evacuation through the duct 13 of air taken from the environment 10. In this case, the suction means 5 are designed to suck in a flow of fresh air and evacuate a flow of internal air in the proportion 70/30. Alternatively, suction means with complete recovery or complete suction can be adopted according to the different system requirements. Downstream of the suction means 5 there is a mixing unit 14, of a known type, which joins the flow of fresh air with the return air coming from the environment 10 through the grille 15 to form the flow of air to be sanitized . The latter is conveyed, in turn, into the dedusting means 6, of a known type, consisting of at least two stages, respectively of mechanical pre-filtering and filtering by electrostatic precipitation. In particular, the pre-filtering stage comprises a pair of filters, respectively in acrylic fiber and metal mesh, which capture the coarser powders with a diameter of between one and 100 microns. Then, the filtering stage by electrostatic precipitation, through the electrifying and capturing sections, stops more minute dusts and consequently the accompanying bacteria and microbes. Downstream of the dedusting means 6 are positioned one or more air conditioning units 16, known per se, designed to give the dedusted air suitable thermo-hygrometric characteristics according to the needs of the environment 10 into which the air will be emitted once. sanitized. At this point, a collector distributes the dedusted and conditioned air in the various conveyor means 8. The ionizing means 7 are positioned within the latter, which consist of emitting electrodes 17 of negative ions uniformly distributed along the conveyor means 8, in position central to the passage section and with the tip pointing in the direction of the air flow. These electrodes 17 create around them an intense negative ionizing field capable of saturating the conveying means 8. This saturation is kept constant during the operation of the device 4 and performs a first action which consists in preventing the formation of molds and bacterial colonies and a second that is expressed in reducing the presence of bacteria, microbes, odors, etc. to a physiological level. in the air in transit. At the end of the conveyor means 8, near the distribution means 9, the neutralizing means 18 are arranged which consist of a positively charged grid 19 which eliminates the negative ions in excess of the air in transit so as to re-establish the correct balance. electrostatic. Therefore, downstream of the neutralizing means 18, immediately before the distribution means 9, there are provided revitalizing means 20 which consist of other emitting electrodes 21 of negative ions (not shown), like the previous ones, which provide the air in transit the electrical characteristics suitable for the environment in which the air will be emitted. Finally, the distributing means 9 are formed by normal grids 9. a or diffusers 9.b, positioned flush with the ceiling surface, which diffuse the sanitized air into the environment. The device is also equipped with a programmable electronic management and control unit 22 which appropriately drives the means described above.

In practice it has been found that the process and the device thus described achieve the intended aim and objects since, thanks to the combination of a dedusting phase and an ionization phase and correspondingly of dedusting and ionizing means, they give the air treated with high purity characteristics. In addition, the device is equipped with a high safety standard since in the event of a failure, for example of the neutralizing means, the control unit intervenes instantly to block the emission of negative ions. Finally, the device can be usefully applied in the curing sites, for example of cheeses, cured meats and in general in those where food products are exposed to free air, as drastically reducing the presence of bacteria and microbes prevents, consequently, the formation of mold on the surface of these products.

The process and the device according to the invention are susceptible of numerous variations and modifications all falling within the scope of the same inventive concept expressed here.

Furthermore, all the details can be replaced by other technically equivalent elements.

In practice, the materials used, as well as the contingent shapes and dimensions, may be any according to requirements.

Where the technical characteristics in the claims are followed by numerical references and / or abbreviations, said numerical references and / or abbreviations have been added for the sole purpose of increasing the intelligibility of the claims and therefore said numerical references and / or abbreviations do not produce any effect. on the scope of each element identified only as an indication by said numerical references and / or abbreviations.

Claims (15)

CLAIMS 1. Process for sanitizing the air and similar gaseous mixtures comprising the initial phase of aspiration of said air to be sanitized and the final phase of inlet of said sanitized air in a closed environment, characterized in that it comprises the intermediate phases of: - dedusting by electrostatic precipitation of said air to be sanitized; - ionization that carries out a bactericidal and microbicidal action in said de-dusted air. 2 Process according to claim 1, characterized in that said ionization is negative, the concentration of said negative ions per unit of dedusted air being at least two orders of magnitude higher than the concentration of ions naturally present and the concentration being constant over time. 3. Process, according to one or more of the preceding claims, characterized in that it comprises at least one conditioning phase of said air to be sanitized to give it characteristics of temperature and humidity suitable for said environment, said conditioning phase being intermediate between said phase of dedusting and the ionization phase. 4. Process according to one or more of the preceding claims, characterized in that it comprises a step of neutralization of excess negative ions by electric elision, said neutralization step being intermediate between said ionization step and said input step. 5. Process according to one or more of the preceding claims, characterized in that it comprises at least one electrostatic revitalization step of said sanitized air by emitting new concentrations of negative ions, said revitalization step being intermediate between said neutralization step and said step of entry. 6. Device for carrying out the procedure for sanitizing air and the like, comprising suction means and means for conveying said air to be sanitized and means for distributing said sanitized air in a closed environment, characterized in that it comprises, in the direction of flow of said air to be sanitized in said conveyor means, dedusting means with electrostatic precipitation and ionizing means of said dusted air. 7. Device according to one or more of the preceding claims, characterized in that said suction means provide for the evacuation of air inside said environment and for the simultaneous suction of air from outside said environment. 8. Device, according to one or more of the preceding claims, characterized in that it comprises at least a mixing unit which joins said external air drawn in with internal air taken from said environment, said mixing unit being arranged downstream of said aspirating means and upstream of said dedusting means. 9. Device according to one or more of the preceding claims, characterized in that said dedusting means comprise at least one mechanical filter and at least one with electrostatic precipitation. 10. Device according to one or more of the preceding claims, characterized in that it comprises at least an air conditioning unit which confers to said dedusted air characteristics of temperature and humidity suitable for said environment, said air conditioning unit being arranged downstream of said dedusting means and upstream of said ionizing means. 11. Device according to one or more of the preceding claims, characterized in that said ionizing means comprise a plurality of electrodes emitting negative ions uniformly distributed along said conveying means, in a central position with respect to the passage section, and facing in the direction of the flow of said dedusted air. 12. Device, according to one or more of the preceding claims, characterized in that it comprises neutralizing means for excess ions in said sanitized air which comprise at least one positively charged grid which by intercepting said sanitized air provides for the electrical elision of said excess ions , said neutralizing means being arranged downstream of said ionizing means in proximity to said distributing means. 13. Device, according to one or more of the preceding claims, characterized in that it comprises revitalizing means consisting of at least one negative ion emission electrode to give said sanitized air suitable electrical characteristics, said revitalizing means being arranged downstream of said neutralizing means and immediately upstream of said distributing means. 14. Device according to one or more of the preceding claims, characterized in that it comprises an electronic control unit which manages said device, 15. Device according to one or more of the preceding claims, characterized in that it comprises one or more of the characteristics described and / or illustrated.