WO2022140870A1 - System and method for sanitising air in rooms - Google Patents

Abstract

The invention relates to the purification of air in enclosed or semi-enclosed environments. Specifically, the invention relates to a system and to a method for sanitising the air in air-conditioned or ventilated rooms by means of systems that operate using ventilation ducts. The main purpose of the invention is to ensure continuous sanitisation of ambient air and surfaces inside one or more rooms where the sanitisation system is operating.

Description

SYSTEM AND METHOD FOR AIR SANITIZATION IN ROOMS

DESCRIPTIVE MEMORY

[0001] The present invention relates to the field of air purification in closed or semi-closed environments. Specifically, the invention refers to a system and a method for sanitizing ambient air and surfaces in air-conditioned rooms by means of air conditioning systems that operate with ventilation ducts.

[0002] The main objective of the invention is to ensure the continuous sanitization of the ambient air and the surfaces inside the room or rooms where the sanitization system operates, through the effective elimination of fungi, bacteria, viruses or other similar organic structures, through the ionization of the air that passes through the ventilation ducts that connect with the room or rooms that must be sanitized.

[0003] Said objective is achieved thanks to the system's capacity to detect any movement of air flow inside the ventilation ducts caused by the activation of the air conditioning systems, in order to start the sanitization process so that the air that makes entrance to the room or rooms is always purified. In the same way, the system is capable of operating in a mode that also allows the sanitization of surfaces that are inside the room.

[0004] Another specific objective of the invention corresponds to the management and monitoring of the sanitization of multiple rooms in the same place, such as a house or building, where the sanitization of the set of rooms is monitored by a central unit, located in remotely, which receives information regarding the operation of the different sanitizing devices, in order to ensure the operation of said devices, as well as the sanitization of each of the rooms.

BACKGROUND

[0005] Currently, the use of air conditioning systems for room air conditioning has become widespread throughout the world, being widely used for air conditioning in hotel rooms, hospitals, offices or any place that requires a temperature suitable at all times to house people. In this sense, one of The most used options correspond to forced draft air conditioning systems that operate through ventilation ducts, where air from the outside enters the system, in order to be cooled or heated, depending on the requirement of the moment, to later be conducted through the different ventilation ducts to air-condition the different rooms. In this process of cooling or heating air, it is necessary to use water, which evaporates in said process. This evaporation of water generates an undesirable increase in humidity, which often causes the accumulation of colonies of organic structures, such as fungi, viruses and bacteria, which travel through the ventilation ducts, finally settling and proliferating in each one. of the rooms.

[0006] To solve this problem, it is common for hotels, offices and hospitals to use air purifying or sanitizing systems, in order to minimize or eliminate as many of these undesirable organic structures as possible. However, despite the technological advances in this field, these systems continue to face challenges related to how to maintain constant and real-time sanitization in each of the rooms where it must be operated, especially in places where the flow or exchange of people is high, as is precisely the case of hotels, hospitals and offices, which are continuously inhabited, in order to improve the services offered. This need to have continuous and effective sanitization increases even more in times when new viruses appear every year, disturbing and often impeding the normal operation of hotels and offices, due to their inability to ensure the guest or worker a space correctly. sanitized, as well as the continuous monitoring of the sanitization tasks in each of the rooms.

[0007] The solutions used by these enclosures are mainly aimed at mobile devices that are installed in the room for a certain period of time so that it can proceed with the purification of the air, or devices that are installed at the outlets of the ventilation ducts that They connect with the different rooms, in order to purify the air before it enters it. Although these solutions fulfill their purpose of purifying the air in rooms, with different degrees of effectiveness and percentages of elimination of organic structures, there are still possibilities for improvements in different specific areas in the field of sanitation, of which they are not done. charge existing solutions. One of these possibilities for improvement is related to the need for the sanitization carried out by the sanitization system to guarantee the elimination of most of the organic structures present in the room in a safe way for people and with less energy consumption. at the same time that it affects to a minimum the free transit of these through the room. [0008] On the other hand, there are several possibilities for improvement in terms of how to operate and control the sanitization system, where it would be desirable to have a system that allows continuous and centralized monitoring of the operation of each of the devices. of sanitization arranged in each of the rooms of the place where the system is located, and that in turn is capable of being integrated into the control and monitoring system of the building's air conditioning system, thus facilitating the operation, control and monitoring by the operator, by being able to visualize the operation of both the air conditioning system and the sanitization system, through a single interface.

[0009] In the field of patents there are solutions that attempt to address some of these possibilities for improvement. For example, patent EP1648593B1 describes an air filtration cartridge suitable for use in treating air in a forced air flow air supply system, wherein the cartridge comprises an inner casing having an upstream portion that defines a chamber having an inlet to receive a forced airflow, and within which is a low power corona discharge ozone generating device. The chamber has an outlet leading to a downstream portion comprising a filter holder and in which a high air flow electrostatic filter is mounted. Although the device described by this document provides a solution that operates in ventilation ducts, thus ensuring that all the air that enters the room is previously purified, said purification is carried out mainly by the production of ozone that occurs in the device mentioned in this document through the physical phenomenon called the corona effect. In this sense, ozone fulfills the function of eliminating certain organic structures, as well as some viruses and bacteria, however, this compound has some drawbacks that make it lose efficiency. One of them is related to the maximum amount of ozone that an ozone-generating device can produce, since if it is continuously inhaled by a person, even in small quantities, the risk of suffering from health problems increases. , such as lung and throat irritation, cough, asthma and other respiratory conditions (see, for example, Chapter 11 of the QMS Air Quality Guidelines, Global Update 2005: particulate matter, ozone, nitrogen dioxide and sulfur dioxide Copenhagen: World Health Organization, 2006

(http:/ywww.euro.who.int./data/assets/pdf_file/0005/78638/E90038.pdf)). which ends up being counterproductive in the objective of maintaining a sanitized environment, free of viruses, fungi and bacteria for the people who live in the different rooms where the device operates.

[0010] Due to these risks to human health, most countries in the world have adopted various regulations regarding the presence of ozone in the environment. For example, The United States is governed by the UL867 Safety Standard for Electrostatic Air Cleaners, which states that a portable product for home use must not produce an ozone concentration greater than 0.05 ppm in a room with a volume between 26 .9 to 31.1 m ³ (ozone emission is controlled for 24 hours to determine the concentration), where in its appendix III it is also indicated that a portable air cleaning product for domestic use may produce a transient concentration of ozone greater than 0.05 ppm, but less than 0.1 ppm, provided that the average of five consecutive one-minute average measurements is less than 0.05 ppm.

[0011] In the case of Chile, the Standard that regulates the presence of ozone in the environment indicates that its concentration must not exceed 0.061 ppm in a period of 8 hours, so all sanitization devices must operate under those levels. of concentration. Therefore, these ozone generating devices can only operate in the absence of people or generating amounts of ozone that are tolerable for them, which in any case maintains the risk to health in the event that the device suffers a malfunction that leads to an increase in the amount of ozone produced to dangerous levels.

[0012] In the case of devices that operate by producing a limited amount of ozone, to be able to operate in the presence of people, as is the case of the device of patent application EP1648593B1, generally said devices are not very reliable for the user, since that the manufacturers, by not providing any type of study or publication that demonstrates the effectiveness of their operation, does not ensure that they are capable of eliminating all types of viruses, bacteria and fungi present in the environment, so that the user of the room will not have the certainty that the environment in which the device operates will be completely free of these organic structures.

[0013] Another example is that disclosed in patent US10426855B2, which describes a system and method for decontaminating indoor air and surfaces that have biological, chemical or physical contamination, where the system is mounted on a wall or similar in the area to be treated. An ozone gas generator is placed inside the system housing to generate ozone gas in the housing. The housing also includes an exhaust fan assembly that exhausts the ozone gas and air mixture from the housing to the area to be treated. The system may run continuously or at predetermined times and for predetermined periods of time. In this case, once again the difference between the present invention and the system and method described in document US10426855B2 lies mainly in the fact that it operates mainly by producing ozone as reactive oxygen species for air purification, which can potentially be harmful to people present in the room to be treated, if you do not have special attention to the concentration levels of ozone emitted in the room, as mentioned in the case of document EP1648593B1, where both systems must adhere to the maximum concentrations allowed by the regulations in force in the country of operation (see also regulations United States and Chile described in paragraphs [0010] and [0011]). In addition, as mentioned above, the lack of studies by the manufacturers of this type of device regarding their effectiveness, according to the concentrations of ozone emitted, makes it impossible to ensure that these devices are capable of of effectively eliminating all the organic structures present in the environment, consequently, not being possible to ensure a totally sanitized environment for the user.

[0014] On the other hand, given that the system presented by this document must be attached to the wall of the room, the air that enters through the ventilation ducts into the interior of the room will not be purified, consequently, the system in constant operation to be able to sanitize the air that enters through the duct, where even so it is not possible to ensure that the person does not breathe air that is not sanitized, as it would be in the case that this person is located next to the ventilation duct .

[0015] Finally, patent application US20040184972A1 describes a method and apparatus for sterilizing a filter medium, which includes the steps of providing a filter element, an atmospheric plasma device capable of generating and dispersing reactive oxidant species, placing the filter element in the water below the plasma device, so that both the surface and the majority of the filter media are exposed to oxidizing reactive species generated from the atmospheric plasma that effect sterilization of the filter element. The atmospheric plasma device corresponds to a radiofrequency, direct current or alternating current pulse power supply, in order to generate the atmospheric plasma and thus create the oxidizing reactive species.

[0016] In relation to this document, it is possible to observe that, although a device is described that sanitizes the air in the room through its ionization, which allows the generation of reactive species, it does not mention what types of reactive species are generated, which is of vital importance to know if a sanitizing device will be able to completely eliminate the presence of viruses, bacteria, fungi and any other organic structure that may be present in the room. In addition, said document does not describe whether the device has the capacity to sanitize the surfaces present in the rooms to be sanitized, nor does it mention whether the described device can be installed in ventilation ducts, in order to ensure that all the air that enter the room is sanitized. [0017] Additionally, none of the documents mentioned above describes a system that has a sensor or device capable of detecting an air movement inside the duct, in order to turn on the sanitization system only when there is effective movement of air towards the interior of the duct. the room, thus preventing the system from consuming energy in situations where the air conditioning system is off.

[0018] Finally, none of the documents described has a central unit that is capable of monitoring the operation and sanitization level of each of the rooms that are being sanitized in a given place, such as a hotel, hospital, offices or any set of rooms that are heated through ventilation ducts, in order to provide all this information in real time to the system operator, in addition to being able to store said information, where the system is also capable of integrating monitoring systems and existing controls in the building associated with the air conditioning system, allowing the operation of the air conditioning system and the sanitization system under a single interface, facilitating the operation by the user.

[0019] Consequently, it is necessary to have a system to sanitize the air and surfaces in air-conditioned or ventilated rooms through systems that operate with ventilation ducts, which is not only capable of quickly and effectively eliminating all organic structures, such such as viruses, fungi and bacteria, through the ionization of the air and the consequent generation of one or more reactive oxygen species, but also carry out these operations without any risk to the health of the users of the rooms. In addition, there is a need to have a system to sanitize the air that allows it to be purified before entering the room, in order to ensure that users will always be in the presence of sanitized air, as well as the surfaces present in the room. Finally, it is necessary to have a system that allows remote and real-time monitoring of the sanitization process and level in multiple rooms of a system operation site, in order to allow the operator to manage and control all sanitization operations in a seamless manner. fast and efficient.

DESCRIPTION OF THE INVENTION

[0020] The invention refers to a system and a method for sanitizing the air and surfaces in air-conditioned or ventilated rooms by means of air conditioning systems that operate with ventilation ducts, which allows a sanitization process to be monitored and controlled in real time in all the rooms in which the system operates. [0021] This system can operate in any type of room that receives ventilation through ventilation ducts, in which the system sanitization device can be arranged, which ionizes the air that flows through the duct, generating seven species reactive oxygen (ROS), which are capable of eliminating most fungi, bacteria, viruses and any other organic structure that may be present in the environment, where the system is also capable of sanitizing the surfaces present in the room, simply by increasing the power of the ionization device, in order to increase the generation of ROS, in order to ensure a sufficient amount of these reactive species, to come into contact with the surfaces of the room.

[0022] According to a first preferred embodiment of the invention, the system for sanitizing the air in at least one room comprises: at least one room, where each room comprises an interior space and surfaces to be sanitized; at least one sanitizing device for air ionization, arranged at the outlet of at least one ventilation duct towards each of the at least one room, where the sanitizing device comprises: o at least one high-speed power supply unit frequency, comprising at least one high frequency module and at least one sequential regulation module, to produce a power signal to generate a dielectric barrier discharge so as to ionize the air; at least one reaction chamber, comprising an air inlet and an air outlet, which configure an open environment within the ventilation duct through which the air that moves from the ventilation duct flows towards each of the al minus one room, to be ionized due to the dielectric barrier discharge generated by the power signal; at least one mass flow sensor that, upon detecting an air flow from the at least one duct to the at least one room, produced by the activation of an air conditioning system in the at least one room, turns on the sanitization device; at least one set of signaling elements, arranged in each of the at least one room, to indicate the sanitization level in which the at least one room is located and/or to indicate if the at least one sanitization device is operating or at rest; at least one communication unit, which sends operation and sanitization level data in each of the at least one room; at least one control unit, which controls the operation of the at least one high-frequency power supply unit, of the at least one reaction chamber, of the at least one mass flow sensor and of the at least one set of signaling elements ; at least one central monitoring unit, which receives the operation and sanitization level data from each of the at least one sanitization device; and at least one power supply, which energizes the at least one sanitizing device, the at least one set of signaling elements, the at least one communication unit and the at least one control unit.

[0023] The sanitization of the air and surfaces in each of the rooms to be treated occurs thanks to the generation of reactive oxygen species through the process of modulated dielectric barrier discharge (MDBD, for its acronym in English), the which allows to ionize the air to produce at least one type of oxidizing compound to eliminate at least one type of organic structure that is present in the air and/or surfaces in the rooms.

[0024] According to another embodiment of the invention, the at least one type of oxidizing compound corresponds to one or more of the group of reactive oxygen species (ROS).

[0025] According to another embodiment of the invention, the at least one type of organic structure includes all types of fungi, bacteria and viruses, in addition to any other organic structure, which are eliminated thanks to the action of the oxidizing compounds generated , allowing to ensure a complete sanitization of each of the rooms to be treated, as well as their surfaces.

[0026] According to another embodiment of the invention, the at least one set of signaling elements corresponds to a set of lights, where the set comprises at least one LED light of the same or different color, to indicate each of the operating modes of the sanitization system and the sanitization level of the room. This allows both the staff in charge of cleaning the rooms, as well as the users of these, to know in real time the level of sanitization of the rooms, from which cleaning protocols can be created to determine the moment in which this is done, in addition to allowing to determine the moment in which a room can be occupied again by a user. [0027] As mentioned above, the sanitization system comprises at least one central monitoring unit, which receives information from each of the control units, which in turn receive information regarding the operation and sanitization level of each of the sanitization devices that are under your control, thanks to the respective communication units. This configuration allows organizing the sanitization of the rooms according to the different needs that the system operator may have at the time, being able to determine which floors or rooms within a floor must be sanitized before others in real time. This is useful in places where the flow of people in each of the rooms cannot be determined in advance, such as in hotels and hospitals, where it is important to take advantage of the times when the user of the room is not there. present to perform cleaning and sanitizing tasks.

[0028] According to another embodiment of the invention, the power supply corresponds to an input to the electrical network arranged in the at least one room, to which the at least one sanitizing device is connected by means of a power cable. Specifically, the system operates with alternating current, in a range of 110-220 VAC.

[0029] According to another embodiment of the invention, the power supply corresponds to a backup system, which operates with electricity or through fossil fuels.

[0030] On the other hand, according to a second preferred embodiment of the invention, a method for sanitizing the air in at least one room is described, comprising the following steps: a) detecting, by means of at least one mass flow sensor, if there is an air flow from at least one ventilation duct into the interior of at least one room, produced by the activation of an air conditioning system in the at least one room; b) in case of detecting that there is an air flow into the at least one room, energizing the at least one device for sanitizing the air by means of at least one power source; c) turning on the at least one sanitizing device; d) produce a power signal, by means of at least one high-frequency power supply unit of the sanitizing device; e) producing at least one type of oxidizing compound due to the dielectric barrier discharge generated by the power signal; f) enter the air flowing through the ventilation duct through the inlet of at least one reaction chamber; g) diffusing the at least one type of oxidizing compound in the at least one reaction chamber, ionizing the air; h) sanitizing the air inside the at least one reaction chamber, by eliminating at least one type of organic structure present in the air through the at least one type of oxidizing compound; and i) letting out the sanitized air with a load of reactive oxygen species through at least one air outlet of the at least one reaction chamber, said sanitized air entering the at least one room.

[0031] According to another embodiment of the invention, the method further comprises operating the sanitization system according to time intervals defined by the user of the room or by the operator of the sanitization system. Being able to set time intervals by the user or operator prevents the sanitization system from operating continuously together with the air conditioning system, in situations where the room user keeps the air conditioning system on for long periods of time. In these cases, the sanitization system will turn off after the time defined by the user or operator has elapsed, thus avoiding any risk of excessive generation and diffusion of reactive oxygen species inside the room, protecting the user's health.

[0032] According to another embodiment of the invention, the detection made by the mass flow sensor is determined to be sufficient to activate the sanitizing device, if the detected flow is equal to or greater than about 3 m/s.

[0033] According to another embodiment of the invention, the method further comprises controlling the power level of the power supply signal, so as to control the dielectric barrier discharge process, which determines the amount of oxidizing compounds to be produced. Being able to control the production power of oxidizing compounds allows the system to operate in different modes, starting from the selection of different power supply voltages, depending on the level of sanitization required or if the user or users of the room are in their inside. For example, the sanitization device can operate in a first mode, at 40VAC, called "safe mode", configured to work with people inside the room, and in a second mode, at 110VAC, called "shock mode", to a deep sanitization of the room. However, the sanitizing device can operate in multiple different modes, covering most of the supply voltage range (50-60-70-80 and 90VAC), depending on the particular application that is needed and on variables such as, for example, the volume of the room, if there are people inside, the time available for sanitization, etc.

[0034] According to another embodiment of the invention, the power level of the power supply signal allows the generation of a quantity of oxidizing compounds sufficient to keep the air in the room sanitized. Said mode of operation allows, for example, to keep the sanitization device in operation in the presence of people in the room, without there being any risk associated with the amount of oxidizing compounds present in the air.

[0035] According to another embodiment of the invention, the power level of the power supply signal allows the generation of a quantity of oxidizing compounds sufficient to keep the air and surfaces within the room sanitized. This modality allows a deep sanitization to be carried out inside the room, which may be necessary in hotel rooms, hospitals and offices, places where the people who occupy a certain room change daily or within the same day, so it is necessary maintain a high level of sanitation.

[0036] According to another embodiment of the invention, the sanitization method further comprises collecting information related to the operation of the sanitization device and the sanitization level of each of the rooms by the at least one control unit associated with each sanitizing device. Said information may correspond to data regarding the supply voltage and current, as well as information on the supply signal produced by the high-frequency supply unit of the sanitizing device.

[0037] In turn, each control unit sends the information collected for each sanitization device to a central monitoring unit, through at least one communication unit, where reports are stored and created regarding the sanitization of each room and on the operation of each of the sanitizing devices in real time, which can be viewed by the system operator, in order to define criteria and times to perform sanitization in each of the rooms according to the needs of the time and the level of occupancy of the rooms. Information is sent by creating links between the communication units and the central monitoring unit, through wireless communication, generally through a ZIGBEE or similar network, where, in turn, the information is sent to a management platform in a data cloud through telephone signals 2G, 3G, 4G, etc., or potentially through any other form of communication wireless. In this sense, the number of central monitoring units present in the system, as well as the number of communication units, will depend on the number of sanitization devices to be monitored, as well as the number of floors in the building. .

[0038] Finally, according to another embodiment of the invention, the method further comprises being integrated into an intelligent management system that operates and delivers information about the air conditioning system of the at least one room, to deliver information regarding the operation of the sanitizing system. Generally, buildings that have air conditioning systems have an administration system that allows controlling the operation of the air conditioning system in each of the rooms independently of each other. Said administration systems are monitored by building personnel, therefore, delivering information regarding the operation and functioning of the sanitization system through this same administration system allows simplifying the monitoring tasks for the personnel in charge. , since from a single platform it is possible to control both the air conditioning system and the sanitization system. This provides the possibility of programming the sanitization of the rooms according to multiple parameters, such as hours of operation, time of operation, power of operation, sanitization with people or without people in the room, etc.

BRIEF DESCRIPTION OF THE FIGURES

[0039] As part of the present invention, the following representative figures are presented, which show preferred embodiments of the invention and, therefore, should not be considered as limiting the definition of the claimed matter.

Figure 1 shows a front isometric view of the reaction chamber of the invention, according to a preferred embodiment.

Figure 2 shows a rear isometric view of the reaction chamber of the invention, according to a preferred embodiment.

Figure 3 shows an isometric view of the sanitizing device of the invention, according to a preferred embodiment.

Figure 4 shows a side view of the sanitizing device of the invention, according to a preferred embodiment. Figure 5 shows a top view of the sanitizing device of the invention, according to a preferred embodiment.

Figure 6 shows a front view of the sanitizing device of the invention, according to a preferred embodiment.

Figure 7 shows a connection diagram between the components that make up the sanitizing system of the invention, according to a preferred embodiment.

Figure 8 shows a diagram of an apartment with several rooms and the layout of the ventilation ducts through which the sanitizing system of the invention operates, according to a preferred embodiment.

Figure 9 shows the communication system used by the system for the sanitization of the invention in a building, according to a preferred embodiment.

DETAILED DESCRIPTION OF MODALITIES OF THE INVENTION

[0040] With reference to the accompanying figures, figures 1 and 2 show a front and rear isometric view of a reaction chamber (20), which is part of the sanitization system, which is connected to a disinfection device. sanitization through two openings (21, 22). Said reaction chamber (20), together with the sanitizing device, are arranged together inside the ventilation duct that leads to the room to be sanitized, thus configuring an open environment inside the ventilation duct through which it flows. the air that moves from the ventilation duct to the room, allowing its ionization due to the dielectric barrier discharge generated by the power signal produced by the sanitization device.

[0041] In relation to figures 3 to 6, these show different views of the sanitizing device (10) for the ionization of the air. Said sanitization device (10) comprises inside a high-frequency power supply unit, which in turn is made up of a high-frequency module and a sequential regulation module, in order to produce the power signal to generate a discharge of dielectric barrier, which is what finally allows the ionization of the air. The sanitization device (10) also comprises two electrodes (11, 12), which are connected to the reaction chamber through the openings (21, 22) to be able to discharge oxidizing compounds into the air that passes through of the ventilation duct.

[0042] Regarding figure 7, it can be seen a connection diagram between the different components of the system for sanitation (1), which is arranged inside of the ventilation duct of the air conditioning system of the building in which the system is operating. Specifically, the sanitizing device (10) is shown coupled to the reaction chamber (20), through the electrodes (11, 12), which allows the discharge of oxidizing compounds through the dielectric barrier discharge phenomenon. In addition, the sanitizing device (10) is mechanically attached to the reaction chamber (20) through two fastening elements (13, 14), which prevent the sanitizing device (10) and the reaction chamber ( 20) become uncoupled.

[0043] On the other hand, Figure 7 also shows a mass flow sensor (30), which is coupled to the rear of the sanitizing device (10). The function of the mass flow sensor (30) is to send a signal to a control unit (40) when it detects that there is an air flow passing through the ventilation duct towards the room to be sanitized, so that it can be the sanitizing device (10) is in operation. This is very important in the operation of the sanitization system (1), since it allows energy savings, since the sanitization device (10) will only operate when there is air flow circulating through the ventilation duct towards the room, which indicates that the air conditioning system has been turned on, also allowing to ensure the ionization of the air every time there is circulation of it through the ventilation duct.

[0044] As mentioned in the previous paragraph, figure 7 also shows a control unit (40), which controls the operation of the sanitizing device (10), specifically its high-frequency power supply unit, as well as it also controls the operation of the reaction chamber (20) and the mass flow sensor (30), which is done through the feed and control ports (41a, 41b) and (42a, 42b).

[0045] In addition, said ports (41a, 41b) and (42a, 42b) allow the control unit (40) to store information related to the operation and level of sanitization of the room from the sanitization device (10). Said information may correspond to data regarding the supply voltage and current, as well as information on the supply signal produced by the high-frequency supply unit of the sanitizing device (10).

[0046] As mentioned earlier in this memory, the control unit (40) is capable of sending the information collected for the sanitization device (10), to a central monitoring unit, through a communication unit, which can store and create reports regarding the sanitization of each room and the operation of each of the sanitizing devices in real time, allowing its visualization by the system operator. [0047] Thanks to the ability of the sanitization system (1) to integrate with the intelligent management system that the building has to operate and monitor everything related to the air conditioning system, it is possible to simplify the monitoring tasks for the personnel in charge of supervising the air conditioning and sanitization of the rooms, since from a single interface it is possible to monitor and control both the air conditioning system and the sanitization system, making it possible to program the sanitization of the rooms according to multiple parameters, such as schedule of operation, time of operation, power of operation, sanitization in the presence of people or without people in the room, etc.

[0048] For its part, Figure 8 shows a diagram of an apartment with several rooms, by way of example, in which the system for sanitizing the air (1) of the invention operates, where a duct is observed of ventilation (100) of the air conditioning system of the building, inside which the sanitization device (10) is housed, together with the reaction chamber (20), the mass flow sensor (30) and the control unit ( 40). In addition, a communication unit (50) may be arranged in the duct together with the control unit (40), and may also be located outside of it, being located in such a way as to be able to receive communication from various control units (40). ) associated with different sanitization devices (10). It is important to note that the components that are arranged inside the duct (100), are located before any bifurcation that said duct (100) may suffer towards other rooms, so that the oxidizing compounds produced by the sanitization device (10 ) disperse to all rooms in the apartment.

[0049] This same figure also shows how the communication unit (50) operates in conjunction with the central monitoring unit (60), where the former wirelessly sends the information collected by the control unit (40) . Said information is related to the operation data regarding the supply voltage and current, as well as information on the supply signal produced by the high-frequency supply unit of the sanitization device (10), being able to also send, optionally , information about the sanitization status of the room. Once the central monitoring unit (60) receives the information from the sanitization devices (10) present in the building, it communicates wirelessly with a cloud (70), where the information is stored securely.

[0050] This is best seen in figure 9, where a sectional view of a building in which the sanitization system (1) operates can be seen. Said figure shows that for each floor of the building the sanitization device(s) (10) communicate with each other, wirelessly, through one or more communication units (50), depending on the square meters covering each floor. Once communication is established on each of the floors of the building, links are created between the respective communication units (50) and the central monitoring unit (60), through wireless communication, generally through a ZIGBEE or similar network, where, in turn, the information is sent to a data cloud management platform (70) through 2G, 3G, 4G telephone signals, etc.

LIST OF NUMERICAL REFERENCES

1 system for sanitization

10 Sanitizing device

11, 12 Electrodes

13, 14 Fasteners

20 reaction chamber

21, 22 Openings

30 Mass flow sensor

40 control unit

41a, 41b Power and control ports

42a, 42b Power and control ports

50 communication unit

60 Central Monitoring Unit

70 Cloud

100 Ventilation duct

Claims

CLAIMS A system for sanitizing the air in at least one room, CHARACTERIZED because it comprises: at least one room, where each room includes an interior space and surfaces to be sanitized; at least one sanitizing device for air ionization, arranged at the outlet of at least one ventilation duct towards each of the at least one room, where the sanitizing device comprises: o at least one high-speed power supply unit frequency, comprising at least one high frequency module and at least one sequential regulation module, to produce a power signal to generate a dielectric barrier discharge so as to ionize the air; at least one reaction chamber, comprising an air inlet and an air outlet, which form a closed environment through which the air that moves from the ventilation duct flows to each of the at least one room, to be ionized due to the dielectric barrier discharge generated by the power signal; at least one mass flow sensor that, upon detecting an air flow from the at least one duct to the at least one room, produced by the activation of an air conditioning system in the at least one room, turns on the sanitization device; at least one set of signaling elements, arranged in each of the at least one room, to indicate the sanitization level in which the at least one room is located and/or to indicate if the at least one sanitization device is operating or at rest; at least one communication unit, which sends operation and sanitization level data in each of the at least one room; at least one control unit, which controls the operation of the at least one high-frequency power supply unit, of the at least one reaction chamber, of the at least one mass flow sensor and of the at least one set of signaling elements ; at least one central monitoring unit, which receives the operation and sanitization level data from each of the at least one sanitization device; Y at least one power supply, which energizes the at least one sanitizing device, the at least one set of signaling elements, the at least one communication unit and the at least one control unit. The system according to claim 1, CHARACTERIZED in that the at least one type of oxidizing compound corresponds to one or more of the group of reactive oxygen species (ROS). The system according to any of claims 1-2, CHARACTERIZED in that the at least one type of organic structure includes all types of fungi, bacteria and viruses, in addition to any other organic structure. The system according to any of claims 1-3, CHARACTERIZED in that the at least one set of signaling elements corresponds to a set of lights, where the set comprises at least one LED light of the same or different color, to indicate each one of the operating modes of the sanitization system and the sanitization level of the room. The system according to any of claims 1-4, CHARACTERIZED in that the power supply corresponds to an input to the electrical network arranged in the at least one room, to which the at least one sanitization device is connected by a cable feeding. The system according to any of claims 1-5, CHARACTERIZED because it operates with alternating current, in a range of 110-220 VAC. The system according to any of claims 1-4, CHARACTERIZED in that the power supply corresponds to a backup system, which operates with electricity or through fossil fuels. The system according to any of claims 1-7, CHARACTERIZED in that the sanitizing device operates at 40 VAC. The system according to any of claims 1-7, CHARACTERIZED in that the sanitizing device operates at 110 VAC. The system according to any of claims 1-7, CHARACTERIZED in that the sanitizing device operates at 50, 60, 70, 80 or 90 VAC. A method for sanitizing the air in at least one room, CHARACTERIZED because it comprises the following steps: a) detect, by means of at least one mass flow sensor, if there is an air flow from at least one ventilation duct into the at least one room, produced by the activation of an air conditioning system in the at least one room; b) in case of detecting that there is an air flow into the at least one room, energizing the at least one device for sanitizing the air by means of at least one power source; c) turning on the at least one sanitizing device; d) produce a power signal, by means of at least one high-frequency power supply unit of the sanitizing device; e) producing at least one type of oxidizing compound due to the dielectric barrier discharge generated by the power signal; f) enter the air flowing through the ventilation duct through the inlet of at least one reaction chamber; g) diffusing the at least one type of oxidizing compound in the at least one reaction chamber, ionizing the air; h) sanitizing the air inside the at least one reaction chamber, by eliminating at least one type of organic structure present in the air through the at least one type of oxidizing compound; and i) letting out the sanitized air with a load of reactive oxygen species through at least one air outlet of the at least one reaction chamber, said sanitized air entering the at least one room. The method according to claim 11, CHARACTERIZED in that it further comprises operating the sanitization system according to time intervals defined by the user of the room or by the operator of the sanitization system. The method according to any of claims 11-12, CHARACTERIZED in that the detection made by the mass flow sensor is determined as sufficient to activate the sanitization device, if the flow detected is equal to or greater than approximately 3 m/s. The method according to any of claims 11-13, CHARACTERIZED in that it also comprises controlling the power level of the power signal, in order to control the dielectric barrier discharge process, which determines the amount of oxidizing compounds to be produced . The method according to any of claims 11-14, CHARACTERIZED in that the power level of the power supply signal allows the generation of a sufficient amount of oxidizing compounds to keep the air inside the room sanitized. The method according to any of claims 11-14, CHARACTERIZED in that the power level of the power supply signal allows the generation of a sufficient amount of oxidizing compounds to keep the air and surfaces within the room sanitized. The method according to any of claims 11-16, CHARACTERIZED in that it further comprises collecting information related to the operation of the sanitization device and the sanitization level of each of the rooms by the at least one control unit. The method according to claim 17, CHARACTERIZED in that the information may correspond to measurements regarding the input voltage and current, as well as regarding details of the power supply signal. The method according to any of claims 11-18, CHARACTERIZED in that each control unit sends the information collected for each sanitization device to the at least one central monitoring unit, through the at least one communication unit, in where reports are stored and created regarding the sanitization of each room and the operation of each of the sanitizing devices in real time. The method according to any of claims 17-19, CHARACTERIZED because the information is sent by creating links between the communication units and the central monitoring unit, through wireless communication, generally through a ZIGBEE or similar network, where, in turn, the information is sent to a management platform in a data cloud through GPRS/GSM (2G/3G) networks or through any other form of communication wireless. The method according to any of claims 11-20, CHARACTERIZED in that it also comprises connecting to an intelligent management system that operates and delivers information about the air conditioning system of the at least one room, to deliver information regarding the operation of the system of sanitization.